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Mastering Physics Solutions Chapter 6 Applications Of Newton’s Laws

May 23, 2018May 22, 2018 by Prasanna

Mastering Physics Solutions Chapter 6 Applications Of Newton’s Laws

Chapter 6 Applications Of Newton’s Laws Q.1CQ
A clothesline always sags a little, even if nothing hangs from it. Explain.
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.1P
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Chapter 6 Applications Of Newton’s Laws Q.2CQ
In the Jurassic Park sequel, The Lost World, a man tries to keep a large vehicle from going over a cliff by connecting a cable from his Jeep to the vehicle. The man then puts the Jeep in gear and spins the rear wheels. Do you expect that spinning the tires will increase the force exerted by the Jeep on the vehicle? Why or why not?
Solution:
No
The man puts the jeep in gear and spins the rear wheels, but spinning will not provide the friction needed to rise above. Spinning the wheels actually decrease the force exerted by the jeep because the force exerted by the spinning wheels is kinetic friction, and the coefficient of kinetic friction is generally less than the coefficient of static friction.

Chapter 6 Applications Of Newton’s Laws Q.2P
Predict/Explain Two drivers traveling side-by-side at the same speed suddenly see a deer in the road ahead of them and begin braking. Driver 1 stops by locking up his brakes and screeching to a halt; driver 2 stops by applying her brakes just to the verge of locking, so that the wheels continue to turn until her car comes to a complete stop. (a) All other factors being equal, is the stopping distance of driver 1 greater than, less than, or equal to the stopping distance of driver 2? (b) Choose the best explanation from among the following:
I. Locking up the brakes gives the greatest possible braking force.
II. The same tires on the same road result in the same force of friction.
III. Locked-up brakes lead to sliding (kinetic) friction, which is less than rolling (static) friction.
Solution:
(a) The stopping distance of driver 1 is greater than the stopping distance of driver 2.
(b) For driver 2 the force stopping the car is the static friction force. And for driver 1 the force stopping the car is the kinetic friction force. But the static friction force is greater than the kinetic friction force. Therefore the driver 1 travels greater than the driver 2. So option III is the best explanation.

Chapter 6 Applications Of Newton’s Laws Q.3CQ
When a traffic accident is investigated, it is common for the length of the skid marks to be measured. How could this information be used to estimate the initial speed of the vehicle that left the skid marks?
Solution:
Braking distance depends on the initial speed and the kinetic friction. If the braking distance and the kinetic friction are known, then the initial speeds of the car can be found.

Chapter 6 Applications Of Newton’s Laws Q.3P
Abaseball player slides into third base with an initial speed of 4.0 m/s. If the coefficient of kinetic friction between the player and the ground is 0.46, how far does the player slide before coming to rest?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.4CQ
In a car with rear-wheel drive, the maximum acceleration is often less than the maximum deceleration. Why?
Solution:
The maximum acceleration is determined by the normal force exerted on the drive wheels. If the engine of the car is in the front and the drive wheels are in the rear, the normal force is less than it would be with front-wheel drive. During braking, however, all four wheels participate – including the wheels that sit under the engine.

Chapter 6 Applications Of Newton’s Laws Q.4P
A child goes down a playground slide with an acceleration of 1.26 m/s2. Find the coefficient of kinetic friction between the child and the slide if the slide is inclined at an angle of 33.0° below the horizontal.
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.5CQ
A train typically requires a much greater distance to come to rest, for a given initial speed, than does a car. Why?
Solution:
The frictional force is responsible for moving the object when the brakes or the driving force are applied. In the case of the train, the frictional force between the rails and the wheels are comparatively low because both are smooth surfaces.
In the case of the car, the road and the rubber tires are both irregular surfaces, so the frictional force is comparatively greater. Therefore, the car stops at a shorter distance than the train.

Chapter 6 Applications Of Newton’s Laws Q.5P
Hopping into your Porsche, you floor it and accelerate at 12 m/s2 without spinning the tires. Determine the minimum coefficient of static friction between the tires and the road needed to make this possible.
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.6CQ
Give some everyday examples of situations in which friction is beneficial.
Solution:
Frictional force is beneficial in the following cases.
(1) Without friction, we cannot walk
(2) Without friction, a car cannot run on the road
(3) Without friction, we cannot hammer the nails inside the walls

Chapter 6 Applications Of Newton’s Laws Q.6P
When you push a 1.80-kg book resting on a tabletop, it takes 2.25 N to start the book sliding. Once it is sliding, however, it takes only 1.50 N to keep the book moving with constant speed. What are the coefficients of static and kinetic friction between the book and the tabletop?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.7CQ
At the local farm, you buy a flat of strawberries and place them on the backseat of the car. On the way home, you begin to brake as you approach a stop sign. At first the strawberries stay put, but as you brake a bit harder, they begin to slide off the seat. Explain.
Solution:
As you brake harder, your car has a greater acceleration. The greater the acceleration of the car, the greater the force required to give the flat strawberries the same acceleration. When the required force exceeds the maximum force of static friction, the strawberries begin to slide.

Chapter 6 Applications Of Newton’s Laws Q.7P
In Problem, what is the frictional force exerted on the book when you push on it with a force of 0.75 N? When you push a 1.80-kg book resting on a tabletop, it takes 2.25 N to start the book sliding. Once it is sliding, however, it takes only 1.50 N to keep the book moving with constant speed. What are the coefficients of static and kinetic friction between the book and the tabletop?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.8CQ
It is possible to spin a bucket of water in a vertical circle and have none of the water spill when the bucket is upside down. How would you explain this to members of your family?
Solution:
When we rotate the bucket vertically, a centripetal force comes to counter the weight of the water that falls down. A sufficiently high speed of rotation gives a sufficient force opposite to the mouth of the bucket, so the water does not fall at all.

Chapter 6 Applications Of Newton’s Laws Q.8P
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Chapter 6 Applications Of Newton’s Laws Q.9CQ
Water sprays off a rapidly turning bicycle wheel. Why?
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Chapter 6 Applications Of Newton’s Laws Q.9P
A tie of uniform width is laid out on a table, with a fraction of its length hanging over the edge. Initially, the tie is at rest. (a) If the fraction hanging from the table is increased, the tie eventually slides to the ground. Explain. (b) What is the coefficient of static friction between the tie and the table if the tie begins to slide when one-fourth of its length hangs over the edge?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.10CQ
Can an object be in equilibrium if it is moving? Explain.
Solution:
Answer: Yes
Explanation:
If a body moving with constant velocity, it acted upon by zero net force. The body is said to be in equilibrium, if net force acting on it is zero. Therefore, object can be in equilibrium if it is moving with a constant velocity.

Chapter 6 Applications Of Newton’s Laws Q.10P
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Chapter 6 Applications Of Newton’s Laws Q.11CQ
In a dramatic circus act, a motorcyclist drives his bike around the inside of a vertical circle. How is this possible, considering that the motorcycle is upside down at the top of the circle?
Solution:
The motorcyclist drives his bike around the inside vertical circle at a very high speed. Because of this high speed, sufficient centripetal force appears away from the center and is much higher than the weight of the motorcyclist and his bike when it is upside down.

Chapter 6 Applications Of Newton’s Laws Q.11P
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Chapter 6 Applications Of Newton’s Laws Q.12CQ
The gravitational attraction of the Earth is only slightly less at the altitude of an orbiting spacecraft than it is on the Earth’s surface. Why is it, then, that astronauts feel weightless?
Solution:
Answer:
In this case, two astronauts are in the constant-free fall motion as they are in orbiting.
For constant free-fall motion, the net gravitational force of attraction acting on the astronauts is zero. Hence, astronauts feel weightless. This is just resembles to the case, if elevator drops downward in free fall motion, you will feel weightless inside the elevator.

Chapter 6 Applications Of Newton’s Laws Q.12P
A 48-kg crate is placed on an inclined ramp. When the angle the ramp makes with the horizontal is increased to 26°, the crate begins to slide downward. (a) What is the coefficient of static friction between the crate and the ramp? (b) At what angle does the crate begin to slide if its mass is doubled?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.13CQ
A popular carnival ride has passengers stand with their backs against the inside wall of a cylinder. As the cylinder begins to spin, the passengers feel as if they are being pushed against the wall. Explain.
Solution:
During the carnival ride, when the cylinder begins to spin, its centripetal force is exerted on the passengers. This force, which is radially inward, is supplied by the wall of the cylinder.

Chapter 6 Applications Of Newton’s Laws Q.13P
A 97-kg sprinter wishes to accelerate from rest to a speed of 13 m/s in a distance of 22 m. (a) What coefficient of static friction is required between the sprinter’s shoes and the track? (b) Explain the strategy used to find the answer to part (a).
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.14CQ
Referring to Question, after the cylinder reaches operating speed, the floor is lowered away, leaving the passengers “stuck” to the wall. Explain.
(Answers to odd-numbered Conceptual Questions can be found in the back of the book.) A popular carnival ride has passengers stand with their backs against the inside wall of a cylinder. As the cylinder begins to spin, the passengers feel as if they are being pushed against the wall. Explain
Solution:
Reaching the operating speed, the centripetal force acting on the man is sufficient to counter his weight, which is responsible for the fall. Thus, even without the base, the man sticks to the wall.

Chapter 6 Applications Of Newton’s Laws Q.14P
Coffee To Go A person places a cup of coffee on the roof of her car while she dashes back into the house for a forgotten item. When she returns to the car, she hops in and takes off with the coffee cup still on the roof. (a) If the coefficient of static friction between the coffee cup and the roof of the car is 0.24, what is the maximum acceleration the car can have without Causing the cup to slide? Ignore the effects of air resistance. (b) What is the smallest amount of time in which the person can accelerate the car from rest to 15 m/s and still keep the coffee cup on the roof?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.15CQ
Your car is stuck on an icy side street. Some students on their way to class see your predicament and help out by sitting on the trunk of your car to increase its traction. Why does this help?
Solution:
Students sitting on the trunk of the car increase the normal force between the tires and the road. The force of friction is directly proportional to the normal, so this increases the frictional force enough so that the car moves.

Chapter 6 Applications Of Newton’s Laws Q.15P
Force Times Distance I At the local hockey rink, a puck with a mass of 0.12 kg is given an initial speed of v = 5.3 m/s. (a) If the coefficient of kinetic friction between the ice and the puck is 0.11, what distance d does the puck slide before coming to rest? (b) If the mass of the puck is doubled, does the frictional force F exerted on the puck increase, decrease, or stay the same? Explain. (c) Does the stopping distance of the puck increase, decrease, or stay the same when its mass is doubled? Explain. (d) For the situation considered in part (a), show that . (The significance of this result will be discussed in Chapter 7, where we will see that is the kinetic energy of an object.)
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.16CQ
The parking brake on a car causes the rear wheels to lock up. What would be the likely consequence of applying the parking brake in a car that is in rapid motion? (Note: Do not try this at home.)
Solution:
If the parking brake is applied while the car is in motion, and the rear wheels begin to skid across the pavement. This means that the friction acting on the rear wheels is kinetic friction. This kinetic friction is smaller than the static friction experienced by the front wheels. As a result, the rear wheels overtake the front wheels causing the car to spin around, and the rear wheels begin to move first.

Chapter 6 Applications Of Newton’s Laws Q.16P
Force Times Time At the local hockey rink, a puck with a mass of 0.12 kg is given an initial speed of v0 = 6.7 m/s. (a) If the coefficient of kinetic friction between the ice and the puck is 0.13, how much time f does it take for the puck to come to rest? (b) If the mass of the puck is doubled, does the frictional force F exerted on the puck increase, decrease, or stay the same? Explain. (c) Does the stopping time of the puck increase, decrease, or stay the same when its mass is doubled? Explain. (d) For the situation considered in part (a), show that Ft = mv0. (The significance of this result will be discussed in Chapter 9, where we will see that mv is the momentum of an object.)
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.17CQ
The foot of your average gecko is covered with billions of tiny hair tips—called spatulae—that are made of keratin, the protein found in human hair. A subtle shift of the electron distribution in both the spatulae and the wall to which a gecko clings produces an adhesive force by means of the van der Waals interaction between molecules. Suppose a gecko uses its spatulae to cling to a vertical windowpane. If you were to describe this situation in terms of a coefficient of static friction, µs, what value would you assign to µs? Is this a sensible way to model the gecko’s feat? Explain.
Solution:
The normal force exerted on a gecko by the vertical wall is zero. For the gecko to stay in place, its static friction must exert an upward force equal to the gecko’s weight. In order for this to happen, the normal force should be zero, and the coefficient of static friction should be infinite.

Chapter 6 Applications Of Newton’s Laws Q.17P
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Chapter 6 Applications Of Newton’s Laws Q.18CQ
Discuss the physics involved in the spin cycle of a washing machine. In particular, how is circular motion related to the removal of water from the clothes?
Solution:
As the basket within a washing machine rotates, the clothes collect on the rim of the basket because of the centripetal force acting on the rotation. The basket exerts an inward force on the clothes, causing them to follow a circular path. The water contained in the clothes, however, is able to pass through the holes of the basket where it can be drained from the machine.

Chapter 6 Applications Of Newton’s Laws Q.18P
The coefficient of kinetic friction between the tires of your car and the roadway is µ. (a) If your initial speed is v and you lock your tires during braking, how far do you skid? Give your answer in terms of v, µ, and m, the mass of your car. (b) If you double your speed, what happens to the stopping distance? (c) What is the stopping distance for a truck with twice the mass of your car, assuming the same initial speed and coefficient of kinetic friction?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.19CQ
The gas pedal and the brake pedal are capable of causing a car to accelerate. Can the steering wheel also produce an acceleration? Explain.
Solution:
Yes, the steering wheel can accelerate a car by changing its direction of motion.

Chapter 6 Applications Of Newton’s Laws Q.19P
A certain spring has a force constant k. (a) If this spring is cut in half, does the resulting half spring have a force constant that is greater than, less than, or equal to k? (b) If two of the original full-length springs are connected end to end, does the resulting double spring have a force constant that is greater than, less than, or equal to k?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.20CQ
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Solution:
People on the outer rim of a rotating space station must experience a force directed toward the center of the station in order to follow a circular path. This force is applied by the floor of the station, which is really its outermost wall. Because people feel the upward force acting on them from the floor, just as they would on Earth, the sensation is like an artificial gravity.

Chapter 6 Applications Of Newton’s Laws Q.20P
Pulling up on a rope, you lift a 4.35-kg bucket of water from a well with an acceleration of 1.78 m/s2. What is the tension in the rope?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.21CQ
When rounding a corner on a bicycle or a motorcycle, the driver leans inward, toward the center of the circle. Why?
Solution:
When a bicycle rider leans inward on a turn, the force applied to the bicycle wheels by the ground is both upward and inward. It is this inward force that produces the rider’s centripetal acceleration.

Chapter 6 Applications Of Newton’s Laws Q.21P
When a 9.09-kg mass is placed on top of a vertical spring, the spring compresses 4.18 cm. Find the force constant of the spring.
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.22CQ
In Robin Hood: Prince of Thieves, starring Kevin Costner, Robin swings between trees on a vine that is on fire. At the lowest point of his swing, the vine bums through and Robin begins to fall. The next shot, from high up in the trees, shows Robin falling straight downward. Would you rate the physics of this scene “Good,” “Bad,” or “Ugly”? Explain.
PROBLEMS AND CONCEPTUAL EXERCISES
Note: Answers to odd-numbered Problems and Conceptual Exercises can be found in the back of the book. IP denotes an integrated problem, with both conceptual and numerical parts; BIO identifies problems of biological or medical interest; CE indicates a conceptual exercise, Predict/Explain problems ask for two responses: (a) your prediction of a physical outcome, and (b) the best explanation among three provided. On all problems, red bullets (,,) are used to indicate the level of difficulty.
SECTION 6-1 FRICTIONAL FORCES
Solution:
The physics of this scene is somewhere between bad and ugly. When the rope burns through, the robin is moving horizontally. This horizontal motion should continue as the robin falls, leading to a parabolic trajectory rather than the straight downward drop shown in the movie.

Chapter 6 Applications Of Newton’s Laws Q.22P
A 110-kg box is loaded into the trunk of a car. If the height of the car’s bumper decreases by 13 cm, what is the force constant of its rear suspension?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.23P
A 50.0-kg person takes a nap in a backyard hammock. Both ropes supporting the hammock are at an angle of 15.0° above the horizontal, Find the tension in the ropes.
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.24P
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Chapter 6 Applications Of Newton’s Laws Q.25P
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Chapter 6 Applications Of Newton’s Laws Q.26P
The equilibrium length of a certain spring with a force constant of k = 250 N/m is 0.18 m. (a) What is the magnitude of the force that is required to hold this spring at twice its equilibrium length? (b) Is the magnitude of the force required to keep the spring compressed to half its equilibrium length greater than, less than, or equal to the force found in part (a)? Explain.
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.27P
Illinois Jones is being pulled from a snake pit with a rope that breaks if the tension in it exceeds 755 N. (a) If Illinois Jones has a mass of 70.0 kg and the snake pit is 3.40 m deep, what is the minimum tune that is required to pull our intrepid explorer from the pit? (b) Explain why the rope breaks if Jones is polled from the pit in less time than that calculated in part (a).
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Chapter 6 Applications Of Newton’s Laws Q.28P
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Chapter 6 Applications Of Newton’s Laws Q.29P
Your friend’s 13.6-g graduation tassel hangs from his rearview mirror. (a) When he acceleration stoplight, the tassel deflects backward toward the car. Explain. (b) If the tassel hangs at an angle of 6.4 the vertical, what is the acceleration of the car?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.30P
In Problem 29, (a) find the tension in the siring holding the tassel. (b) At what angle to the vertical will the tension in the string be twice the weight of the tassel?
Problem 29
Your friend’s 13.6-g graduation tassel hangs on a string from his rearview mirror. (a) When he accelerates from a stoplight, the tassel deflects backward toward the rear of the car. Explain. (b) If the tassel hangs at an angle of 6.44° relative to the vertical, what is the acceleration of the car?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.31P
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Chapter 6 Applications Of Newton’s Laws Q.32P
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Chapter 6 Applications Of Newton’s Laws Q.33P
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Chapter 6 Applications Of Newton’s Laws Q.34P
Pulling the string on a bow back with a force of 28.7 lb, an archer prepares to shoot an arrow. If the archer pulls in the center of the string, and the angle between the two halves is 138°, what is the tension in the string?
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Chapter 6 Applications Of Newton’s Laws Q.35P
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Chapter 6 Applications Of Newton’s Laws Q.41P
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Chapter 6 Applications Of Newton’s Laws Q.42P
In Example (Connected Blocks), suppose m1 and m2 are both increased by a factor of 2. (a) Does the acceleration of the blocks increase, decrease, or stay the same? (b) Does the tension in the string increase, decrease, or stay the same?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.43P
CE Predict/Explain Suppose m1 and m2 in Example (Atwood’s Machine) are both increased by 1 kg. Does the acceleration of the blocks increase, decrease, or stay the same? (b) Choose the best explanation from among the following:
I. The net force acting on the blocks is the same, but the total mass that must be accelerated is greater.
II. The difference in the masses is the same, and this is what determines the net force on the system.
III. The force exerted on each block is greater, leading to an increased acceleration.
Solution:
(a) The acceleration decreases when both the masses are increased by 1kg.
(b) This is because of the net force acting on the blocks is same, but the total mass that must be accelerated is greater. Therefore option I is the best explanation.

Chapter 6 Applications Of Newton’s Laws Q.44P
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Chapter 6 Applications Of Newton’s Laws Q.46P
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Chapter 6 Applications Of Newton’s Laws Q.48P
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Chapter 6 Applications Of Newton’s Laws Q.49P
A 7.7-N force pulls horizontally on a 1.6-kg block that slides on a smooth horizontal surface. This block is connected by a horizontal string to a second block of mass m2 = 0.83 kg on the same surface, (a) What is the acceleration of the blocks? (b) What is the tension in the string? (c) If the mass of block 1 is increased, does the tension in the string increase, decrease, or stay the same?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.50P
Buckets and a Pulley Two buckets of sand hang from opposite ends of a rope that passes over an ideal pulley. One bucket is full and weighs 120 N; the other bucket is only partly filled and weighs 63 N. (a) Initially, you hold onto the lighter bucket to keep it from moving. What is the tension in the rope? (b) You release the lighter bucket and the heavier one descends. What is the tension in the rope now? (c) Eventually the heavier bucket lands and the two buckets come to rest. What is the tension in the rope now?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.51P
Suppose you stand on a bathroom scale and get a reading of 700 N. In principle, would the scale read more, less, or the same if the Earth did not rotate?
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Chapter 6 Applications Of Newton’s Laws Q.52P
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Chapter 6 Applications Of Newton’s Laws Q.53P
A car is driven with constant speed around a circular track. Answer the of the following questions with “Yes” or “No.” (a) Is the car’s velocity constant? (b) Is its speed constant? (c) Is the magnitude of its acceleration constant? (d) Is the direction of its acceleration constant?
Solution:
(a) No.
As the direction of the car is changing time to time, therefore the velocity of the car is not constant.
(c) Yes
The magnitude of acceleration is constant, as it is proportional to the square of the speed of the car which is constant.
(d) No, the direction of acceleration is not constant. It changes from point to point.

Chapter 6 Applications Of Newton’s Laws Q.54P
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Solution:
Consider a puck attached to a string undergoes circular motion on an air table. If the string breaks at a point on the circumference of the circle,
The motion of the puck directed along a tangential line drawn to the circle at that mentioned point.
From given diagram the motion of the puck will be path B from diagram clearly know that path B is the tangential to the circle at given point.

Chapter 6 Applications Of Newton’s Laws Q.55P
When you take your 1300-kg car out for a spin, you go around a corner of radius 59 m with a speed of 16 m/s. The coefficient of static friction between the car and the road is 0.88. Assuming your car doesn’t skid, what is the force exerted on it by static friction?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.56P
Find the linear speed of the bottom of a test tube in a centrifuge if the centripetal acceleration there is 52,000 times the acceleration of gravity. The distance from the axis of rotation to the bottom of the test tube is 7.5 cm.
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.57P
A Human Centrifuge To test the effects of high acceleration on the human body, the National Aeronautics and Space Administration (NASA) has constructed a large centrifuge at the Manned Spacecraft Center in Houston. In this device, astronauts are placed in a capsule that moves in a circular path with a radius of 15 m. If the astronauts in this centrifuge experience a centripetal acceleration 9.0 times that of gravity, what is the linear speed of the capsule?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.58P
A car goes around a curve on a road that is banked at an angle of 33.5°. Even though the road is slick, the car will stay on the road without any friction between its tires and the road when its speed is 22.7 m/s. What is the radius of the curve?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.59P
Jill of the Jungle swings on a vine 6.9 m long. What is the tension in the vine if Jill, whose mass is 63 kg, is moving at 2.4 m/s when the vine is vertical?
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.60P
In Problem, (a) how does the tension in the vine change if Jill’s speed is doubled? Explain. (b) How does the tension change if her mass is doubled instead? Explain.
Jill of the Jungle swings on a vine 6.9 m long. What is the tension in the vine if Jill, whose mass is 63 kg, is moving at 2.4 m/s when the vine is vertical?
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Chapter 6 Applications Of Newton’s Laws Q.61P
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Chapter 6 Applications Of Newton’s Laws Q.63P
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Chapter 6 Applications Of Newton’s Laws Q.64P
You swing a 4.6-kg bucket of water in a vertical circle of radius 1.3 m. (a) What speed must the bucket have if it is to complete the circle without spilling any water? (b) How does your answer depend on the mass of the bucket?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws64ps

Chapter 6 Applications Of Newton’s Laws Q.65GP
If you weigh yourself on a bathroom scale at the equator, is the reading you get greater than, less than, or equal to the reading you get if you weigh yourself at the North Pole?
Solution:
Your weight at North Pole is greater than your weight at the equator.
At equator you are moving in a circular path because of the rotation of earth. Therefore part of the force of gravity acting on you is providing your centripetal acceleration. And the rest shows up as a reduced weight on the scale. But at North Pole you are not moving in a circular path. Therefore the force of gravity shows up as weight on the scale. Therefore the reading you get on the bath room scale for your weight at equator is less than the reading you get on the bath room scale for your weight at North Pole.

Chapter 6 Applications Of Newton’s Laws Q.66GP
An object moves on a flat surface with an acceleration of constant magnitude. If the acceleration is always perpendicular to the object’s direction of motion, (a) is the shape of the object’s path circular, linear, or parabolic? (b) During its motion, does the object’s velocity change in direction but not magnitude, change in magnitude but not direction, or change in both magnitude and direction? (c) Does its speed increase, decrease, or stay the same?
Solution:
(a) Here the magnitude of acceleration of the object is constant and the acceleration is always perpendicular to the object’s direction of motion. Therefore the shape of the path is circular.
(b) As the acceleration is perpendicular to the direction of motion, therefore the direction of the velocity changes but not its magnitude.
(c) As there is no acceleration in the direction of the motion of the object, therefore the speed of the object stay the same.

Chapter 6 Applications Of Newton’s Laws Q.67GP
BIO Maneuvering a Jet Humans lose consciousness if exposed to prolonged accelerations of more than about 7g. This is of concern to jet fighter pilots, who may experience centripetal accelerations of this magnitude when making high-speed turns. Suppose we would like to decrease the centripetal acceleration of a jet. Rank the following changes in flight path in order of how effective they are in decreasing the centripetal acceleration, starting with the least effective: A, decrease the turning radius by a factor of two; B, decrease the speed by a factor of three; or C; increase the turning radius by a factor of four.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws67ps

Chapter 6 Applications Of Newton’s Laws Q.68GP
Gravitropism As plants grow, they tend to align their stems and roots along the direction of the gravitational field. This tendency, which is related to differential concentrations of plant hormones known as auxins, is referred to as gravitropism. As an illustration of gravitropism, experiments show that seedlings placed in pots on the rim of a rotating turntable do not grow in the vertical direction. Do you expect their stems to tilt inward—toward the axis of rotation—or outward—away from the axis of rotation?
Solution:
The direction of growth of a plant is opposite to the effective direction of gravitational force at that place. If a growing plant is kept on the rim of a rotating table, it tilts inwards.
Consider the example of a simple pendulum kept on the rim of the turntable. When the table is at rest, the pendulum hangs vertically downwards while the plant grows vertically upwards. When the table is rotating, the pendulum tilts outward, and plant tilts in the opposite direction, i.e., inward.

Chapter 6 Applications Of Newton’s Laws Q.69GP
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws69p
Solution:

Chapter 6 Applications Of Newton’s Laws Q.70GP
Find the centripetal acceleration at the top of a test tube in a centrifuge, given that the top is 4.2 cm from the axis of rotation and that its linear speed is 77 m/s.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws70ps

Chapter 6 Applications Of Newton’s Laws Q.71GP
Find the coefficient of kinetic friction between a 3.85-kg block and the horizontal surface on which it rests if an 850-N/m spring must be stretched by 6.20 cm to pull it with constant speed. Assume that the spring pulls in the horizontal direction.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws71ps

Chapter 6 Applications Of Newton’s Laws Q.72GP
A child goes down a playground slide that is inclined at an angle of 26.5° below the horizontal. Find the acceleration of the child given that the coefficient of kinetic friction between the child and the slide is 0.315.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws72gps

Chapter 6 Applications Of Newton’s Laws Q.73GP
When a block is placed on top of a vertical spring, the spring compresses 3.15 cm. Find the mass of the block, given that the force constant of the spring is 1750 N/m.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws73gps

Chapter 6 Applications Of Newton’s Laws Q.74GP
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws74gp
Solution:

Chapter 6 Applications Of Newton’s Laws Q.75GP
A force of 9.4 N pulls horizontally on a 1.1-kg block that slides on a rough, horizontal surface. This block is connected by a horizontal string to a second block of mass m2 = 1.92 kg on the same surface. The coefficient of kinetic friction is µk = 0.24 for both blocks. (a) What is the acceleration of the blocks? (b) What is the tension in the string?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws75gps

Chapter 6 Applications Of Newton’s Laws Q.76GP
You swing a 3.25-kg bucket of water in a vertical circle of radius 0.950 m. At the top of the circle the speed of the bucket is 3.23 m/s; at the bottom of the circle its speed is 6.91 m/s. Find the tension in the rope tied to the bucket at (a) the top and (b) the bottom of the circle.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws76gps

Chapter 6 Applications Of Newton’s Laws Q.77GP
A 14-g coin slides upward on a surface that is inclined at an angle of 18° above the horizontal. The coefficient of kinetic friction between the coin and the surface is 0.23; the coefficient of static friction is 0.35. Find the magnitude and direction of the force of friction (a) when the coin is sliding and (b) after it comes to rest.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws77gps

Chapter 6 Applications Of Newton’s Laws Q.78GP
In Problem, the angle of the incline is increased to 25°. Find the magnitude and direction of the force of friction when the coin is (a) sliding upward initially and (b) sliding back downward later.
A 14-g coin slides upward on a surface that is inclined at an angle of 18° above the horizontal. The coefficient of kinetic friction between the coin and the surface is 0.23; the coefficient of static friction is 0.35. Find the magnitude and direction of the force of friction (a) when the coin is sliding and (b) after it comes to rest.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws78gps

Chapter 6 Applications Of Newton’s Laws Q.79GP
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Chapter 6 Applications Of Newton’s Laws Q.80GP
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Chapter 6 Applications Of Newton’s Laws Q.81GP
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Chapter 6 Applications Of Newton’s Laws Q.82GP
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Chapter 6 Applications Of Newton’s Laws Q.83GP
A picture hangs on the wall suspended by two strings, as shown in Figure. The tension in string 2 is 1.7 N. (a) Is the tension in string 1 greater than, less than, or equal to 1.7 N? Explain. (b) Verify your answer to part (a) by calculating the tension in string 1. (c) What is the mass of the picture?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws83gps

Chapter 6 Applications Of Newton’s Laws Q.84GP
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Chapter 6 Applications Of Newton’s Laws Q.85GP
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Chapter 6 Applications Of Newton’s Laws Q.86GP
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Chapter 6 Applications Of Newton’s Laws Q.87GP
Find the coefficient of kinetic friction between a 4.7-kg block and the horizontal surface on which it rests if an 89-N/m spring must be stretched by 2.2 cm to pull the block with constant speed. Assume the spring pulls in a direction 13° above the horizontal.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws87gp

Chapter 6 Applications Of Newton’s Laws Q.88GP
Solution:
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Chapter 6 Applications Of Newton’s Laws Q.89GP
In a daring rescue by helicopter, two men with a combined mass of 172 kg are lifted to safety. (a) If the helicopter lifts the men straight up with constant acceleration, is the tension in the rescue cable greater than, less than, or equal to the combined weight of the men? Explain. (b) Determine the tension in the cable if the men are lifted with a constant acceleration of 1.10 m/s2.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws89gps

Chapter 6 Applications Of Newton’s Laws Q.90GP
At the airport, you pull a 18-kg suitcase across the floor with a strap that is at an angle of 45° above the horizontal. Find (a) the normal force and (b) the tension in the strap, given that the suitcase moves with constant speed and that the coefficient of kinetic friction between the suitcase and the floor is 0.38.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws90gps

Chapter 6 Applications Of Newton’s Laws Q.91GP
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Solution:

Chapter 6 Applications Of Newton’s Laws Q.92GP
A 0.16-g spider hangs from the middle of the first thread of its future web. The thread makes an angle of 7.2° with the horizontal on both sides of the spider. (a) What is the tension in the thread? (b) If the angle made by the thread had been less than 7.2°, would its tension have been greater than, less than, or the same as in part (a)? Explain.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws92gps

Chapter 6 Applications Of Newton’s Laws Q.93GP
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Chapter 6 Applications Of Newton’s Laws Q.94GP
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Chapter 6 Applications Of Newton’s Laws Q.95GP
A pair of fuzzy dice hangs from a string attached to your rearview mirror. As you turn a corner with a radius of 98 m and a constant speed of 27 mi/h, what angle will the dice make with the vertical? Why is it unnecessary to give the mass of the dice?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws95gps

Chapter 6 Applications Of Newton’s Laws Q.96GP
Find the tension in the of the two ropes supporting a hammock if one is at an angle of 18° above the horizontal and the other is at an angle of 35° above the horizontal. The person sleeping in the hammock (unconcerned about tensions and ropes) has a mass of 68 kg.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws96gps

Chapter 6 Applications Of Newton’s Laws Q.97GP
As your plane circles an airport, it moves in a horizontal circle of radius 2300 in with a speed of 390 km/h. If the lift of the airplane’s wings is perpendicular to the wings, at what angle should the plane be banked so that it doesn’t tend to slip sideways?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws97gps

Chapter 6 Applications Of Newton’s Laws Q.98GP
A block with a mass of 3.1 kg is placed at rest on a surface inclined at an angle of 45° above the horizontal. The coefficient of static friction between the block and the surface is 0.50, and a force of magnitude F pushes upward on the block, parallel to the inclined surface. (a) The block will remain at rest only if F is greater than a minimum value, Fmin, and less than a maximum value, Fmax. Explain the reasons for this behavior. (b) Calculate Fmin. (c) Calculate Fmax.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws98gps

Chapter 6 Applications Of Newton’s Laws Q.99GP
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Chapter 6 Applications Of Newton’s Laws Q.100GP
A child sits on a rotating merry-go-round, 2.3 m from its center. If the speed of the child is 2.2 m/s, what is the minimum coefficient of static friction between the child and the merry-go-round that will prevent the child from slipping?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws100gps

Chapter 6 Applications Of Newton’s Laws Q.101GP
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Solution:

Chapter 6 Applications Of Newton’s Laws Q.102GP
A wood block of mass m rests on a larger wood block of mass M that rests on a wooden table. The coefficients of static and kinetic friction between all surfaces are µs and µk, respectively. What is the minimum horizontal force, F, applied to the lower block that will cause it to slide out from under the upper block?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws102gps

Chapter 6 Applications Of Newton’s Laws Q.103GP
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws103gp
Solution:

Chapter 6 Applications Of Newton’s Laws Q.104GP
The coefficient of static friction between a rope and the table on which it rests is µs. Find the fraction of the rope that can hang over the edge of the table before it begins to slip.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws104gps

Chapter 6 Applications Of Newton’s Laws Q.105GP
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Chapter 6 Applications Of Newton’s Laws Q.106GP
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Chapter 6 Applications Of Newton’s Laws Q.107GP
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Chapter 6 Applications Of Newton’s Laws Q.108GP
A Conveyor Belt A box is placed on a conveyor belt that moves with a constant speed of 1.25 m/s. The coefficient of kinetic friction between the box and the belt is 0.780. (a) How much time does it take for the box to stop sliding relative to the belt? (b) How far docs the box move in this time?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws108gps

Chapter 6 Applications Of Newton’s Laws Q.109GP
You push a box along the floor against a constant force of friction. When you push with a horizontal force of 75 N, the acceleration of the box is 0.50 m/s2; when you increase the force to 81 N, the acceleration is 0.75 m/s2. Find (a) the mass of the box and (b) the coefficient of kinetic friction between the box and the floor.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws109gps

Chapter 6 Applications Of Newton’s Laws Q.110GP
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws110gp
Solution:

Chapter 6 Applications Of Newton’s Laws Q.111PP
On the straight-line segment I in Figure we see that increasing the applied mass from 26 g to 44 g results in a reduction of the end-to-end distance from 21 mm to 14 mm. What is the force constant in N/m on segment I?
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws111gp
Solution:

Chapter 6 Applications Of Newton’s Laws Q.112PP
Is the force constant on segment II greater than, less than, or equal to the force constant on segment I?
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws112gp
Solution:
As the slope of the curve in the segment II is less than the slope of the curve in the segment I, therefore the force constant on segment II is less than the force constant on segment I.

Chapter 6 Applications Of Newton’s Laws Q.113PP
Which of the following is the best estimate for the force constant on segment II?
A. 0.83 N/m
B. 1.3 N/m
C. 2.5 N/m
D. 25 N/m
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws113gp
Solution:

Chapter 6 Applications Of Newton’s Laws Q.114PP
Rank the straight segments I, II, and III in order of increasing “stiffness” of the nasal strip.
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws114gp
Solution:
The stiffness is more for the segment having more force constant. Here the force constant is more for the segment III and less for the segment II. Therefore the rank of the segments in the increasing order of the stiffness is III, I and then II.

Chapter 6 Applications Of Newton’s Laws Q.115IP
Referring to Example Suppose the coefficients of static and kinetic friction between the crate and the truck bed are 0.415 and 0.382, respectively. (a) Does the crate begin to slide at a tilt angle that is greater than, less than, or equal to 23.2°? (b) Verify your answer to part (a) by determining the angle at which the crate begins to slide. (c) Find the length of time it takes for the crate to slide a distance of 2.75 m when the tilt angle has the value found in part (b).
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws115gps

Chapter 6 Applications Of Newton’s Laws Q.116IP
Referring to The crate begins to slide when the tilt angle is 17.5°. When the crate reaches the bottom of the flatbed, after sliding a distance of 2.75 m, its speed is 3.11 m/s. Find (a) the coefficient of static friction and (b) the coefficient of kinetic friction between the crate and the flatbed.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws116gps

Chapter 6 Applications Of Newton’s Laws Q.117IP
Referring to Example Suppose that the mass on the frictionless tabletop has the value m1 = 2.45 kg. (a) Find the value of m2 that gives an acceleration of 2.85 m/s2. (b) What is the corresponding tension; T, in the string? (c) Calculate the ratio T/m2g and show that it is less than 1, as expected.
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws117gps

Chapter 6 Applications Of Newton’s Laws Q.118IP
Referring to Example At what speed will the force of static friction exerted on the car by the road be equal to half the weight of the car? The mass of the car is m = 1200 kg, the radius of the corner is r = 45 m, and the coefficient of static friction between the tires and the road is µs = 0.82. (b) Suppose that the mass of the car is now doubled, and that it moves with a speed that again makes the force of static friction equal to half the car’s weight. Is this new speed greater than, less than, or equal to the speed in part (a)?
Solution:
Mastering Physics Solutions Chapter 6 Applications Of Newton's Laws118gps

Mastering Physics Solutions Chapter 32 Nuclear Physics and Nuclear Radiation

May 22, 2018 by Raju

Mastering Physics Solutions Chapter 32 Nuclear Physics and Nuclear Radiation

Mastering Physics Solutions

Chapter 32 Nuclear Physics and Nuclear Radiation Q.1CQ
Nucleus A and nucleus B have different numbers of protons and different numbers of neutrons. Explain how it is still possible for these nuclei to have equal radii.
Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.1P

Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.2CQ
When α particles are emitted in a nuclear decay, they have well-defined energies. In contrast, ß particles are found to be emitted with a range of energies. Explain this difference.
Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.2P

Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.3CQ
Is it possible for a form of heavy hydrogen to decay by emitting an α particle? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-3cq

Chapter 32 Nuclear Physics and Nuclear Radiation Q.3P

Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-3p1

Chapter 32 Nuclear Physics and Nuclear Radiation Q.4CQ
Which is more likely to expose film kept in a cardboard box, α particles or ß particles? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-4cq

Chapter 32 Nuclear Physics and Nuclear Radiation Q.4P
A certain chlorine nucleus has a radius of approximately 4.0 × 10−15 m. How many neutrons are in this nucleus?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-4p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.5CQ
It is not possible for a stable nucleusto contain more than one proton without also having at least one neutron. Explain why neutrons are necessary in a stable, multiparticle nucleus.
Solution:
No. It is not possible for a stable nucleus to have more than one proton and no neutrons.
If the nucleus has only protons, the nucleus would be unstable and blow apart because of the electrostatic repulsion between the protons.
If neutrons are present, they separate the protons, reducing the mutual repulsion between them. Also, the presence of neutrons adds a strong attractive nuclear force, enabling the nuclei to hold it together.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.5P
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.6CQ
Different isotopes of a given element have different masses, but they have the same chemical properties. Explain why chemical properties are unaffected by a change of isotope.
Solution:
Isotopes are elements with same atomic number but different mass numbers.That means the isotopes of an element have same number of protons and electrons but different number of neutrons. The electrons are responsible for chemical reactions.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.6P
IP (a) What initial kinetic energy must an alpha particle bave if it is to approach a stationary gold nucleus to within a distance of 22.5 fm?
(b) If the initial speed of the alpha particle is reduced by a factor of 2,bywhat factor is the distance of closest approach changed? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-6p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.7CQ
(a) Give three examples of objects for winch carbon-14 dating would give useful results.
(b) Give three examples of objects for which carbon-14 dating would not be useful.
Solution:
(a) Carbon-14 dating is useful to date specimen’s upto about 45,000 years old.
It is useful for dating organic materials like human and animal remains like
bones, ivory tusks, burnt bones, also cloth, pottery, paper, hide etc.
(b) Carbon dating is not very useful for dating inorganic materials like rocks and organic materials like fossils which are a million years old, inorganic carbon in shell, etc.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.7P
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.8CQ
Explain why the large, stable nuclei in Figure 32-1 are found to lie above the N = Z line, ratherthan below the une.
Solution:
The nucleus that does not undergo radioactive decay is defined as the stable nuclei.
The elements above the N = Z line will have more neutrons than protons. These neutrons spread out the positive charge of the protons making the nuclei stable.
The nucleii below the N = Z line have more number of protons than the number of neutrons. These protons repel each other blowing the nucleus apart.
Therefore the elements above the N = Z line are said to be stable nuclei.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.8P
Suppose a marble with a radius of 1.5 cm has the density of a nucLeus, as given in Example 32–2.
(a) What is the mass of this marble?
(b) How many of these marbles would be required to have a mass equal to the mass of Earth?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-8p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.9CQ
Suppose each of the following items is about 10,000 years old: a feather, a tooth, an obsidian arrowhead, a deer hide moccasin. Which of these items cannot be dated with carbon-14? Explain.
Solution:
Carbon dating is applicable only to matter which was once living (which has biological origin) and presumed to be in equilibrium with the atmosphere.
A feather, a tooth, a deer hide moccasin are all of biological origin. But obsidian is not of biological origin and so it cannot dated with carbon-14.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.9P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.10CQ
Can carbon-14 dating give the age of fossil dinosaur skeletons? Explain.
Solution:
No. Carbon-14 dating is useful to date specimen’s upto about 45,000 years old. But dinosaurs are thousands of times too old to be dated by this technique.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.10P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.11CQ
Two different samples contain the same radioactive isotope. Is it possible for these samples to have different activities? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-11cq

Chapter 32 Nuclear Physics and Nuclear Radiation Q.11P
IP Suppose a uraninm-236 nucleus undergoes fission by splitting into two smaller nuclei of equal size.
(a) Is the radius of each of the smaller nuclei one-half, more than one-half, or less than one-half the radius of the uranium-236 nucleus? Explain.
(b) Calculate the radius of the uranium-236 nucleus.
(c) Calculate the radii of the two smaller nuclei.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-11p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.12CQ
Two samples contain different radioactive isotopes. Is it possible for these samples to have the same activity? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-12cq

Chapter 32 Nuclear Physics and Nuclear Radiation Q.12P
A hypothetical nucleus weighs 11b.
(a) How many nucleons are in this nucleus?
(b) What is the radius of this nucleus?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-12p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.13CQ
Two different types of radiation deliver the same amount of energy to a sample of tissue. Does it follow that each of these types of radiation has the same RBE? Explain.
Solution:
No,
RBE is the acronym for relative biological effective ness. RBE is related to the extent of biological effect caused by a radiation RBE is not related to the amount of energy it gives. So the RBE of two different types of radiation giving same amount of energy are not equal.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.13P
CE Predict/Explain Consider a nucleus that undergoes α decay.
(a) Is the radius of the resulting daughter nucleus greater than, less than, or equal to the radius of the original nucleus?
(b) Choose the test explanation from among the following:
I. The decay adds an alpha particle to the nucleus, causing its radius to increase.
II. When the nucleus undergoes decay it ejects two neutrons and two protons. This decreases the number of nucleons in the nucleus, and therefore its radius will decrease.
III. An α decay leaves the number of nucleons unchanged. As a result, the radius of the nucleus stays the same.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-13p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.14P
CE Predict/Explain Consider a nucleus that undergoes ß decay.
(a) Is the radius of the resulting daughter nucleus greater than, less than, or the same as that of the original nucleus?
(b) Choose the best explanation from among the following:
I. Capturing a ß particle will cause the radius of a nucleus to increase. Therefore, the daughter nucleus has the greater radius.
II. The original nucleus emits a ß particle, and anytime a particle is emitted from a nucleus the result is a smaller radius. Therefore, the radius of the daughter nucleus is less than the radius of the original nucleus,
III. When a nucleus emits a β particle a neutron is convened proton, but the number of nucleons is unchanged. As a result, the radius of the daughter nucleus is the same as that of the original nucleus.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-14p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.15P
CE Which of the three decay processes (α, ß or γ)results in a new element? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-15p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.16P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.17P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.18P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.19P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.20P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.21P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.22P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.23P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.24P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.25P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.26P
CE The half-life of carbon-14 is 5730 y.
(a) Is it possible for a particular nucleus in a sample of carbon-14 to decay after only 1 s has passed? Explain.
(b) Is it possible for a particular nucleus to decay after 10,000 y? Explain.
Solution:
Yes. The half-life of carbon-14 nucleus is 5,730 y. The half-life of the carbon-14 nucleus represents the average time required for half of a large number of nuclei to decay. A given nucleus in a sample of carbon-14 can decay after only 1 s, because it has a random nature of radioactive decay.
Yes. A given nucleus in a sample of carbon-14 can decay after 10,000 y has passed, because it has a random nature of radioactive decay.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.27P
CE Suppose we were to discover that the ratio of carbon-14 to carbon-12 in the atmosphere was significantly smaller 10,000 yearsago than it is today. How would this affect the ages we have assigned to objects on the basis of carbon-14 dating? In particular, would the true age of an object be greater than or less than the age we had previously assigned to it? Explain.
Solution:
We use carbon 14 dating method to find the ages. If the ratio C – 14 to C – 12 is small 10,000 years ago, then initial amount of carbon – 14 might have been smaller. Then less time is needed for the decay state to reduce to its present value. The age of an object measured in this case will be less than the true age of the object.

Chapter 32 Nuclear Physics and Nuclear Radiation Q.28P
CE A radioactive sample is placed in a closed container. Two days later only one-quarter of the sample is still radioactive. What is the half-life of this sample?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-28p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.29P
Radon gas has a half-life of 3.82 d. What is the decay constant for radon?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-29p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.30P
A radioactive substance has a decay constant equal to 8.9 × 10−3 s−1. What is the half-life of this substance?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-30p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.31P
The number of radioactive nuclei in a particular sample decreases over a period of 18 d to one-sixteenth the original number. What is the half-life of these nuclei?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-31p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.32P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.33P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.34P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.35P
An archeologist on a dig finds a fragment of an ancient basket woven from grass. Later, it is determined that the carbon-14 content of the grass in the basket is 9.25% that of an equal carbon sample from present-day grass. What is the age of the basket?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-35p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.36P
The bones of a saber-toothed tiger are found to have an activity per gram of carbon that is 15.0% of what would be found in a similar live animal. How old are these bones?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-36p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.37P
Charcoal from an ancient fire pit is found to have a carbon-14 content that is only 17.5% that of an equivalent sample of carbon from a living tree. What is the age of the fire pit?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-37p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.38P
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.39P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.40P
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.41P
The atomic mass of gold-197 is 196.96654 u. How much energy is required to completely separate the nucleons in a gold-197 nucleus?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-41p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.42P
The atomic mass of lithrum-7 is 7.016003 u. How much energy is required to completely separate the nucleons in a lithium-7 nucleus?
Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.43P

Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.44P

Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.45P

Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.46P
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.47P
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Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.48P
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Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.49P
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Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.50P
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Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.51P
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.52P
Assuming a release of 173 MeV per fission reaction, calculate how many reactions must occur per second to produce a power output of 150 MW.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-52p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.53P
Consider a fusion reaction in which two deuterium nuclei fuse to form a tritium nucleus and a proton. Mow much energy is released in this reaction?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-53p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.54P
Consider a fusion reaction in which a proton fuses with a neutron to form a deuterium nucleus. How much energy is released in this reaction?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-54p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.55P
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Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.56P
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Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-56p1

Chapter 32 Nuclear Physics and Nuclear Radiation Q.57P
The Evaporating Sun The Sun radiates energy at the prodigious rate of 3.90 × 1026 W.
(a) At what rate, in kilograms per second, does the Sun convert mass into energy?
(b) Assuming that the Sun has radiated at this same rate for its entire lifetime of 4.50 × 109 y, and that the current mass of the Sun is 2.00 × 1030 kg, what percentage of its original mass has been converted to energy?.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-57p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.58P
BIO Radiation Damage A sample of tissue absorbs a 55-rad dose of α particles (RBE = 20).
How many rad of protons (RBB = 10) cause the same amount of damage to the tissue?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-58p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.59P
BIO X-ray Damage How many rad of 200-keV X-rays cause the same amount of biological damage as 50 rad of heavy ions?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-59p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.60P
IP BIO
(a) Find the energy absorbed by a 78-kg person who is exposed to 52 mrem of α particles with an “RBE of 15.
(b) If the RBE of the α particles is increased, does the energy absorbed increase, decrease, or stay the same? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-60p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.61P
BIO A patient undergoing radiation therapy for cancer receives a 225-rad dose of radiation.
(a) Assuming the cancerous growth has a mass of 0.17 kg, calculate how much energy it absorbs.
(b) Assuming the growth to have the specific heat of water, determine its increase in temperature.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-61p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.62P
BIO Alpha particles with an RBE of 13 deliver a 32-mrad whole-body radiation dose to a 72-kg patient.
(a) What dosage, in rem, does the patient receive?
(b) How much energy is absorbed by the patient?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-62p

Chapter 32 Nuclear Physics and Nuclear Radiation Q.63P
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.64GP
CE An α particle (charge + 2e)and a ß particle (charge − e) deflect in opposite directions when they pass through a mag netic field. Which particle defLects by a greater amount, give: that both particles have the same speed? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-64gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.65GP
CE Radioactive samples A and B have equal half-lives. The initial activity of sample A is twice that of sample B. What is the ratio of the activity of sample A to that of sample B after two half-lives have elapsed?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-65gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.66GP
CE The initial activity of sample A is twice that of sample B After two half-lives of sample A have elapsed, the two samples have the same activity. What is the ratio of the half-life of B to the half-life of A?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-66gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.67GP
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.68GP

Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.69GP
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.70GP
Suppose it is desired to give a cancerous tumor a dose of 3800 rem. How many rads are needed if the tumor is exposed to alpha radiation?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-70gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.71GP
A patient is exposed to 260 rad of gamma rays. What is the dose the patient receives in rem?
Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.72GP
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Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.73GP
Moon Rocks In one of the rocks brought back from the Moon, it is found that 80.5% of the initial potassium-40 in the rock has decayed to argon-40.
(a) If the half-life for this decay is 1.20 × 109 years, how old is the rock?
(b) How much longer will it take before only 10.0% of the original potassium-40 is still present in the rock?
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-73gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.74GP
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.75GP
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.76GP
An α particle fired head-on at a stationary nickel nucleus approaches to a radius of 15 fm
before being turned around.
(a) What is the maximum Coulomb force exerted on the α particle?
(b) What is the electric potential energy of the α particle at its point of closest approach?
(c) Find the initial kinetic energy of the α particle.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-76gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.77GP
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.78GP
IP Initially, a sample of radioactive nuclei of type A contains four times as many nuclei as a sample of radioactive nuclei of type B. Two days later (2.00 d) the two samples contain the same number of nuclei.
(a) Which type of nucleus has the longer half-life? Explain.
(b) Determine the half-life of type B nuclei if the half-life of type A nuclei is known to be 0.500 d.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-78gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.79GP
Stable nuclei have mass numbers that range from a minimum of 1 to a maximum of 209.
(a) Find the corresponding range in nuclear radii.
(b) Assuming all nuclei to be spherical, determine the ratio of the surface area of the largest stable nucleus to the surface area of the smallest nucleus.
(c) Repeat part (b), only this time find the ratio of the volumes.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-79gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.80GP
Radius of a Neutron Star Neutron stars are so named because they are composed of neutrons and have a density the same as that of a nucleus. Referring to Example 32–2 for the nuclear density, find the radius of a neutron star whose mass is 0.50 that of the Sun.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-80gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.81GP
A specimen taken from the wrappings of a mummy contains 7.82 g of carbon and has an activity of 1.38 Bq. How old is the mummy? (Refer to pages 1132 and 1133 for relevant information regarding the isotopes of carbon.)
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-81gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.82GP
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Solution:

Chapter 32 Nuclear Physics and Nuclear Radiation Q.83GP
IP Energy is released when three α particles fuse to form carbon-12.
(a) Is the mass of carbon-12 greater than, less than, or the same as the mass of three α particles? Explain.
(b) Calculate the energy given off in this fusion reaction.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-83gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.84GP
Find the dose of y rays that must be absorbed by a block of ice at 0 °C to convert it to water at 0 °C.-Givc the dosage inrad.
Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.85GP
IP
(a) What dosage (in rad) must a 1.0-kg sample of water absorb to increase its temperature by 1.0 C°?
(b) Tf the mass of the water sample is increased, does the dosage found in part (a) increase, decrease, or stay the same? Explain.
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-85gp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.86GP
BIO Chest X-rays A typical chest X-ray uses X-rays with an RBE of 0.85. If the radiation dosage is 35 mrem, find the energy absorbed by a 72-kg patient, assuming one-quarter of the patient’s body is exposed to the X-rays.
Solution:
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.87GP
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.88GP
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.89GP
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Chapter 32 Nuclear Physics and Nuclear Radiation Q.90PP
What is the decay constant, A, for iodine-131?
A. 9.98 ×10−7 s−1
B. 1.44 × ×10−6 s−1
C. 2.39 ×10−5 s−1
D. 5.99 ×10−5 s−1
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-90pp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.91PP
If a sample of iodine-131 contains 4.5 × 1016 nuclei, what is the activity of the sample?
Express your answer in curies.
A. 0.27 Ci
B. 1.2 Ci.
C. 1.7 Ci
D. 4.5 Ci
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-91pp

Chapter 32 Nuclear Physics and Nuclear Radiation Q.92PP
If the half-life of iodine-131 were only half of its actual value, would the activity of the sample in Problem be increased or decreased?
Problem
If a sample of iodine-131 contains 4.5 × 1016 nuclei, what is the activity of the sample? Express your answer in curies.
A. 0.27 Ci
B. 1.2 Ci.
C. 1.7 Ci
D. 4.5 Ci
Solution:
mastering-physics-solutions-chapter-32-nuclear-physics-and-nuclear-radiation-92pp

Mastering Physics Solutions Chapter 5 Newton’s Laws Of Motion

May 21, 2018May 21, 2018 by Prasanna

Mastering Physics Solutions Chapter 5 Newton’s Laws Of Motion

Mastering Physics Solutions

Chapter 5 Newton’s Laws Of Motion Q.1CQ
Driving down the road, you hit the brakes suddenly. As a result, your body moves toward the front of the car. Explain, using Newton’s laws.
Solution:
When the brakes are applied, the car slows down. The body, however, keeps moving at the same speed. Thus, because of inertia, the body moves toward the front of the car.
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion1cqs

Chapter 5 Newton’s Laws Of Motion Q.1P
CE An object of mass m is initially at rest. After a force of magnitude F acts on it for a time T, the object has a speed v. Suppose the mass of the object is doubled, and the magnitude of the force acting on it is quadrupled. In terms of T, how long does it take for the object to accelerate from rest to a speed v now?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion1ps

Chapter 5 Newton’s Laws Of Motion Q.2CQ
You’ve probably seen pictures of someone pulling a tablecloth out from under glasses, plates, and silverware set out for a formal dinner. Perhaps you’ve even tried it yourself. Using Newton’s laws of motion, explain how this stunt works.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion2cqs

Chapter 5 Newton’s Laws Of Motion Q.2P
On a planet far, far away, an astronaut picks up a rock. The rock has a mass of 5.00 kg, and on this particular planet its weight is 40.0 N. Tf the astronaut exerts an upward force of 46.2 N on the rock, what is its acceleration?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion2ps

Chapter 5 Newton’s Laws Of Motion Q.3CQ
As you read this, you arc most likely sitting quietly in a chair. Can you conclude, therefore, that you are at rest? Explain.
Solution:
You are not at absolute rest, you are at rest with respect to the other objects in your surroundings. However when you are viewed from other planets, you are not at rest relative to the vantage point of the other planets.

Chapter 5 Newton’s Laws Of Motion Q.3P
In a grocery store, you push a 12.3-kg shopping cart with a force of 10.1 N. If the cart starts at rest, how far does it move in 2.50 s?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion3ps

Chapter 5 Newton’s Laws Of Motion Q.4CQ
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion4cq
Solution:
When a dog shakes its body, the water remains at rest because of inertia. The water drops fall away from the body when the position of the dog’s body is changed rapidly.

Chapter 5 Newton’s Laws Of Motion Q.4P
You are pulling your little sister on her sled across an icy (fric-tionless) surface. When you exert a constant horizontal force of 120 N, the sled has an acceleration of 2.5 m/s2. If the sled has a mass of 7.4 kg, what is the mass of your little sister?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion4ps

Chapter 5 Newton’s Laws Of Motion Q.5CQ
A young girl slides down a rope. As she slides faster and faster she tightens her grip, increasing the force exerted on her by the rope. What happens when this force is equal in magnitude to her weight? Explain.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion5cqs

Chapter 5 Newton’s Laws Of Motion Q.5P
· A 0.53-kg billiard ball initially at rest is given a speed of 12 m/s during a time interval of 4.0 ms. What average force acted on the ball during this time?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion5ps

Chapter 5 Newton’s Laws Of Motion Q.6CQ
A drag-racing car accelerates forward because of the force exerted on it by the road. Why, then, does it need an engine? Explain.
Solution:
The drag racer needs an engine to turn the wheels, which in turn makes them push against the ground. When the wheels push against the ground, the ground is able to exert a reaction force on the car to move it.

Chapter 5 Newton’s Laws Of Motion Q.6P
A 92-kg water skier floating in a lake is pulled from rest to a speed of 12 m/s in a distance of 25 m. What is the net force exerted on the skier, assuming his acceleration is constant?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion6ps

Chapter 5 Newton’s Laws Of Motion Q.7CQ
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion7cq
Solution:
(A) The upper string is exposed to two forces. One is the downward weight attached and the other is the force applied. So, in this case, the upper string will break.
(B) Because of the inertia of the block, the lower string will break.

Chapter 5 Newton’s Laws Of Motion Q.7P
CE Predict/Explain You drop two balls of equal diameter from the same height at the same time. Ball 1 is made of metal and has a greater mass than ball 2, which is made of wood. The upward force due to air resistance is the same for both balls, (a) Is the drop time of ball 1 greater than, less than, or equal to the drop time of ball 2? (b) Choose the best explanation from among the following:
I. The acceleration of gravity is the same for all objects, regardless of mass.
II. The more massive ball is harder to accelerate.
III. Air resistance has less effect on the more massive ball.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion7ps

Chapter 5 Newton’s Laws Of Motion Q.8CQ
An astronaut on a space walk discovers that his jet pack no longer works, leaving him stranded 50 m from the spacecraft. If the jet pack is removable, explain how the astronaut can still use it to return to the ship.
Solution:
The astronaut should push the jetpack away from him, in the opposite direction from the spaceship. As a result, the reaction force exerted on him by the pack will accelerate him toward the ship.

Chapter 5 Newton’s Laws Of Motion Q.8P
IP A 42.0-kg parachutist is moving straight downward with a speed of 3.85 m/s. (a) If the parachutist comes to rest with constant acceleration over a distance of 0.750 m, what force does the ground exert on her? (b) If the parachutist comes to rest over a shorter distance, is the force exerted by the ground greater than, less than, or the same as in part (a)? Explain.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion8ps

Chapter 5 Newton’s Laws Of Motion Q.9CQ
Two untethered astronauts on a space walk decide to take a break and play catch with a baseball. Describe what happens as the game of catch progresses.
Solution:
Each time the astronauts catch or throw, an equal and opposite force acts on them. This causes the astronauts to move farther from each other, with increasing speed.

Chapter 5 Newton’s Laws Of Motion Q.9P
IP In baseball, a pitcher can accelerate a 0.15-kg ball from rest to 98 mi/h in a distance of 1.7 m. (a) What is the average force exerted on the ball during the pitch? (b) If the mass of the ball is increased, is the force required of the pitcher increased, decreased, or unchanged? Explain.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion9ps

Chapter 5 Newton’s Laws Of Motion Q.10CQ
What are the action-reaction forces when a baseball bat hits a fast ball? What is the effect of each force?
Solution:
Because of action-reaction forces, the ball will be returned with the same force that the ball applied to the bat.
The force exerted on the bat by the ball is action force, and the force exerted on the ball by the bat is reaction force.
The force exerted on the ball changes its direction.

Chapter 5 Newton’s Laws Of Motion Q.10P
A major-league catcher gloves a 92-mi/h pitch and brings it to rest in 0.15 m. If the force exerted by the catcher is 803 N, what is the mass of the ball?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion10ps

Chapter 5 Newton’s Laws Of Motion Q.11CQ
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion11cq
Solution:
Mr. Ed’s reasoning is incorrect because he is adding two action-reaction forces that act on different objects.
Wilbur should point out that the net force exerted on the cart is simply the force exerted on it by Mr. Ed, and so the cart will accelerate.
The equal and opposite reaction force acts on Mr. Ed, and does not cancel the force acting on the cart.

Chapter 5 Newton’s Laws Of Motion Q.11P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion11p
Solution:

Chapter 5 Newton’s Laws Of Motion Q.12CQ
A whole brick has more mass than half a brick, thus the whole brick is harder to accelerate. Why doesn’t a whole brick fall more slowly than half a brick? Explain.
Solution:
The whole brick also experiences twice the gravitational force.
As a result, these two effects (more inertia, more force) cancel each other out exactly. The free-fall acceleration is independent of mass.

Chapter 5 Newton’s Laws Of Motion Q.12P
Stopping a 747 A 747 jetliner lands and begins to slow to a stop as it moves along the runway. If its mass is 3.50 × 105 kg, its speed is 27.0 m/s, and the net braking force is 4.30 × 105 N, (a) what is its speed 7.50 s later? (b) How far has it traveled in this time?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion12ps

Chapter 5 Newton’s Laws Of Motion Q.13CQ
The force exerted by gravity on a whole brick is greater than the force exerted by gravity on half a brick. Why, then, doesn’t a whole brick fall faster than half a brick? Explain.
Solution:
Acceleration of the whole brick is the same as that of half the brick. This is because acceleration is directly proportional to force and inversely proportional to mass.

Chapter 5 Newton’s Laws Of Motion Q.13P
IP A drag racer crosses the finish line doing 202 mi/h and promptly deploys her drag chute (the small parachute used for braking), (a) What force must the drag chute exert on the 891-kg car to slow it to 45.0 mi/h in a distance of 185 m? (b) Describe the strategy you used to solve part (a).
SECTION 5-4 NEWTON’S THIRD LAW OF MOTION
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion13ps

Chapter 5 Newton’s Laws Of Motion Q.14CQ
Is it possible for an object at rest to have only a single force acting on it? If your answer is yes, provide an example. If your answer is no, explain why not.
Solution:
No.
If only a single force acts on the object, it will not stay at rest but will accelerate in the direction of the force.

Chapter 5 Newton’s Laws Of Motion Q.14P
CE Predict/Explain A small car collides with a large truck, (a) Is the magnitude of the force experienced by the car greater than, less than, or equal to the magnitude of the force experienced by the truck? (b) Choose the best explanation from among the following:
I. Action-reaction forces always have equal magnitude.
II. The truck has more mass, and hence the force exerted on it is greater.
III. The massive truck exerts a greater force on the lightweight car.
Solution:
(a) The magnitude of the force experienced by the car is equal to magnitude of the force experienced by the truck.
(b) This is because action reaction forces are always equal in magnitude according to ’s third law. So, option I is the best explanation.

Chapter 5 Newton’s Laws Of Motion Q.15CQ
Is it possible for an object to be in motion and yet have zero net force acting on it? Explain.
Solution:
Yes.
When the object is moving with a constant velocity, its acceleration is zero. Thus, the force acting on the object is also zero.

Chapter 5 Newton’s Laws Of Motion Q.15P
CE Predict/Explain A small car collides with a large truck, (a) Is the acceleration experienced by the car greater than, less than, or equal to the acceleration experienced by the truck? (b) Choose the best explanation from among the following:
I. The truck exerts a larger force on the car, giving it the greater acceleration.
II. Both vehicles experience the same magnitude of force, therefore the lightweight car experiences the greater acceleration.
III. The greater force exerted on the truck gives it the greater acceleration.
Solution:
(a) The acceleration experienced by the car is greater than the acceleration experienced by the truck.
(b) This is because of both cars experience same magnitude of force, therefore the lightweight car experiences greater acceleration. So, option II is the best explanation.

Chapter 5 Newton’s Laws Of Motion Q.16CQ
A bird cage, with a parrot inside, hangs from a scale. The parrot decides to hop to a higher perch. What can you say about the reading on the scale (a) when the parrot jumps, (b) when the parrot is in the air, and (c) when the parrot lands on the second perch? Assume that the scale responds rapidly so that it gives an accurate reading at all times.
Solution:
(a) The scale goes down at the moment the parrot jumps.
This happens because the parrot pushes down on its perch in order to jump, and as a result the scale reads a larger value.
(b) When the bird is in the air, the scale just reads the weight of the cage.
(c) When the parrot lands on a higher perch, the scale goes down and then reads a higher value again. This happens because the perch exerts an upward force on the bird in order to bring the bird to rest.

Chapter 5 Newton’s Laws Of Motion Q.16P
You hold a brick at rest in your hand. (a) How many forces act on the brick? (b) Identify these forces, (c) Are these forces equal in magnitude and opposite in direction? (d) Are these forces an action-reaction pair? Explain.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion16ps

Chapter 5 Newton’s Laws Of Motion Q.17CQ
Suppose you jump from the cliffs of Acapulco and perform a perfect swan dive. As you fall, you exert an upward force on the Earth equal in magnitude to the downward force the Earth exerts on you. Why, then, does it seem that you are the one doing all the accelerating? Since the forces are the same, why aren’t the accelerations?
Solution:
The acceleration of a body is inversely proportional to its mass. Earth has a huge mass compared to a man, and so has negligible acceleration towards the man. Thus, the forces are the same but not the accelerations.

Chapter 5 Newton’s Laws Of Motion Q.17P
Referring to Problem 16, you are now accelerating the brick upward, (a) How many forces act on the brick in this case? (b) Identify these forces, (c) Are these forces equal in magnitude and opposite in direction? (d) Are these forces an action-reaction pair? Explain.
Solution:
(A) There are two forces.
(B) Gravitational force and the upward force applied by your hand.
(C) No, these forces are not equal and opposite since the brick is moving up.
(D) No.

Chapter 5 Newton’s Laws Of Motion Q.18CQ
A friend tells you that since his car is at rest, there are no forces acting on it. How would you reply?
Solution:
The car is at rest, and the net force acting on the car is zero.
However, it is wrong to say that no force is acting on the car. When the car is at rest, gravitational force acts on the car, which is balanced by the normal force reaction of the ground upon the car.

Chapter 5 Newton’s Laws Of Motion Q.18P
On vacation, your 1400-kg car pulls a 560-kg trailer away from a stoplight with an acceleration of 1.85 m/s2, (a) What is the net force exerted on the trailer? (b) What force does the traiter exert on the car? (c) What is the net force acting on the car?
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.19CQ
Since all objects are “weightless” in orbit, how is it possible for an orbiting astronaut to tell if one object has more mass than another object? Explain.
Solution:
If an astronaut pushes the object, the acceleration can indicate the object’s mass. The heavier mass will have lower acceleration compared to the lighter mass.

Chapter 5 Newton’s Laws Of Motion Q.19P
IP A 71-kg parent and a 19-kg child meet at the center of an ice rink. They place their hands together and push, (a) Is the force experienced by the child more than, less than, or the same as the force experienced by the parent? (b) Is the acceleration of the child more than, less than, or the same as the acceleration of the parent? Explain, (c) If the acceleration of the child is 2.6 m/s2 in magnitude, what is the magnitude of the parent’s acceleration?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion19ps

Chapter 5 Newton’s Laws Of Motion Q.20CQ
To clean a rug, you can hang it from a clothesline and beat it with a tennis racket. Use Newton’s laws to explain why beating the rug should have a cleansing effect.
Solution:
As you hit the rug with the tennis racket you cause it to accelerate rapidly.
The dust from the rug, if it is not attached too firmly, will be left behind as the rug accelerates away from it.

Chapter 5 Newton’s Laws Of Motion Q.20P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion20p
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Chapter 5 Newton’s Laws Of Motion Q.21CQ
If you step off a high board and drop to the water below, you plunge into the water without injury. On the other hand, if you were to drop the same distance onto solid ground, you might break a leg. Use Newton’s laws to explain the difference.
Solution:
When we jump on the ground, we plunge a very small distance compared to jumping into water. The smaller the distance, the larger the acceleration, and thus the greater the force.

Chapter 5 Newton’s Laws Of Motion Q.21P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion21p
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Chapter 5 Newton’s Laws Of Motion Q.22CQ
A moving object is acted on by a net force. Give an example of a situation in which the object moves (a) in the same direction as the net force, (b) at right angles to the net force, or (c) in the opposite direction of the net force.
Solution:
(a) When a cart is pushed forward and set into motion, the direction of the force acting on it and the direction of its motion are equal.
(b) If a ball or any object is thrown up, then, at the top of its flight, its motion is in the horizontal direction. Additionally, the force of gravity acting on the ball (or any object) is in the vertical direction. Here, the direction of force and the direction of motion are perpendicular to each other. In this example, air resistance is neglected.
(c) While you are riding a bicycle, the frictional force acts in the direction opposite to the direction of motion of the bicycle.
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion22cqs

Chapter 5 Newton’s Laws Of Motion Q.22P
IP Two boxes sit side-by-side on a smooth horizontal surface. The lighter box has a mass of 5.2 kg; the heavier box has a mass of 7.4 kg. (a) Find the contact force between these boxes when a horizontal force of 5.0 N is applied to the light box. (b) If the 5.0-N force is applied to the heavy box instead, is the contact force between the boxes the same as, greater than, or less than the contact force in part (a)? Explain, (c) Verify your answer to part (b) by calculating the contact force in this case.
Solution:

Chapter 5 Newton’s Laws Of Motion Q.23CQ
Is it possible for an object to be moving in one direction while the net force acting on it is in another direction? If your answer is yes, provide an example. If your answer is no, explain why not.
Solution:
Yes, during the journey of a ball thrown upward, the direction of force is always downward. Thus, the force is in an opposite direction until the ball reaches its maximum height, and then it comes back down.

Chapter 5 Newton’s Laws Of Motion Q.23P
CE A skateboarder on a ramp is accelerated by a nonzero net force. For each of the following statements, state whether it is always true, never true, or sometimes true, (a) The skateboarder is moving in the direction of the net force, (b) The ac-celeration of the skateboarder is at right angles to the net force. (c) The acceleration of the skateboarder is in the same direction as the net force. (d) The skateboarder is instantaneously at rest.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion23ps

Chapter 5 Newton’s Laws Of Motion Q.24CQ
Since a bucket of water is “weightless” in space, would it hurt to kick the bucket? Explain.
Solution:
Answer: Yes
Explanation:
It is given that the bucket of water is weightless in space, but every object has a certain mass, and also has inertia. As inertia is the tendency of a body to resist any change in its state of motion or rest, so when you kick the bucket, it resists a change in its state of motion by exerting an equal and opposite force, which gives the hurt to your foot.

Chapter 5 Newton’s Laws Of Motion Q.24P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion24p
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Chapter 5 Newton’s Laws Of Motion Q.25CQ
In the movie The Rocketeer, a teenager discovers a jet-powered backpack in an old barn. The backpack allows him to fly at incredible speeds. In one scene, however, he uses the backpack to rapidly accelerate an old pickup truck that is being chased by “bad guys.” He does this by bracing his arms against the cab of the pickup and firing the backpack, giving the truck the acceleration of a drag racer. Is the physics of this scene “Good,” “Bad,” or “Ugly?” Explain.
Solution:
This scene is an example of bad physics. It is true that the jet-powered backpack produces enough force to push the truck, but this force is imparted to the truck through the arms of the teenager. This is a very unrealistic situation, because force that is great enough to accelerate an old truck would likely crush the teenager’s arms.

Chapter 5 Newton’s Laws Of Motion Q.25P
A farm tractor tows a 3700-kg trailer up an 18° incline with a steady speed of 3.2 m/s. What force does the tractor exert on the trailer? (Ignore friction.)
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.26CQ
List three common objects that have a weight of approximately 1 N.
Solution:
Any object whose weight is approximately 100g has a weight equal to 1N
(i) An apple weighs approximately 1N
(ii) A chocolate bar
(iii) A pack of crayons

Chapter 5 Newton’s Laws Of Motion Q.26P
A surfer “hangs ten,” and accelerates down the sloping face of a wave. If the surfer’s acceleration is 3.25 m/s2 and friction can be ignored, what is the angle at which the face of the wave is inclined above the horizontal?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion26ps

Chapter 5 Newton’s Laws Of Motion Q.27P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion27p
Solution:

Chapter 5 Newton’s Laws Of Motion Q.28P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion28p
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Chapter 5 Newton’s Laws Of Motion Q.29P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion29p
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Chapter 5 Newton’s Laws Of Motion Q.30P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion30p
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Chapter 5 Newton’s Laws Of Motion Q.31P
IP Before practicing his routine on the rings, a 67-kg gymnast stands motionless, with one hand grasping each ring and his feet touching the ground. Both aims slope upward at an angle of 24° above the horizontal, (a) If the force exerted by the rings on each arm has a magnitude of 290 N, and is directed along the length of the arm, what is the magnitude of the force exerted by the floor on his feet? (b) If the angle his arms make with the horizontal is greater that 24°, and everything else remains the same, is the force exerted by the floor on his feet greater than, less than, or the same as the valne found in part (a)? Explain.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.32P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion32p
Solution:

Chapter 5 Newton’s Laws Of Motion Q.33P
An object acted on by three forces moves with constant velocity. One force acting on the object is in the positive x direction and has a magnitude of 6.5 N; a second force has a magnitude of 4.4 N and points in the negative y direction. Find the direction and magnitude of the third force acting on the object.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion33ps

Chapter 5 Newton’s Laws Of Motion Q.34P
· A train is traveling up a 3.73° incline at a speed of 3.25 m/s when the last car breaks free and begins to coast without friction, (a) How long does it take for the last car to come to rest momentarily? (b) How far did the last car travel before mo-mentarily coming to rest?
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.35P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion35p
Solution:

Chapter 5 Newton’s Laws Of Motion Q.36P
You pull upward on a stuffed suitcase with a force of 105 N, and it accelerates upward at 0.705 m/s2. What are (a) the mass and (b) the weight of the suitcase?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion36ps

Chapter 5 Newton’s Laws Of Motion Q.37P
BIO Brain Growth A newborn baby’s brain grows rapidly. In fact, it has been found to increase in mass by about 1.6 mg per minute, (a) How much does the brain’s weight increase in one day? (b) How long does it take for the brain’s weight to increase by 0.15 N?
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.38P
Suppose a rocket launches with an acceleration of 30.5 m/s2. What is the apparent weight of an 92-kg astronaut aboard this rocket?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion38ps

Chapter 5 Newton’s Laws Of Motion Q.39P
At the bow of a ship on a stormy sea, a crewman conducts an experiment by standing on a bathroom scale. In calm waters, the scale reads 182 lb. During the storm, the crewman finds a maximum reading of 225 lb and a minimum reading of 138 lb. Find (a) the maximum upward acceleration and (b) the maximum downward acceleration experienced by the crewman.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.40P
IP As part of a physics experiment, you stand on a bathroom scale in an elevator. Though your normal weight is 610 N, the scale at the moment reads 730 N. (a) Is the acceleration of the elevator upward, downward, or zero? Explain. (b) Calculate the magnitude of the elevator’s acceleration. (c) What, if anything, can you say about the velocity of the elevator? Explain.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.41P
When you weigh yourself on good old terra firma (solid ground), your weight is 142 lb. In an elevator your apparent weight is 121 lb. What are the direction and magnitude of the elevator’s acceleration?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion41ps

Chapter 5 Newton’s Laws Of Motion Q.42P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion42p
Solution:

Chapter 5 Newton’s Laws Of Motion Q.43PWhen you lift a bowling ball with a force of 82 N, the ball accelerates upward with an acceleration a. If you lift with a force of 92 N, the ball’s acceleration is 2a. Find (a) the weight of the bowling ball, and (b) the acceleration a.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.44P
A 23-kg suitcase is being pulled with constant speed by a handle that is at an angle of 25° above the horizontal. If the normal force exerted on the suitcase is 180 N, what is the force F applied to the handle?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion44ps

Chapter 5 Newton’s Laws Of Motion Q.45P
(a) Draw a free-body diagram for the skier in Problem 32. (b) Determine the normal force acting on the skier.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion45ps

Chapter 5 Newton’s Laws Of Motion Q.46P
· A 9.3-kg child sits in a 3.7-kg high chair. (a) Draw a free-body diagram for the child, and find the normal force exerted by the chair on the child. (b) Draw a free-body diagram for the chair, and find the normal force exerted by the floor on the chair.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.47P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion47p
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Chapter 5 Newton’s Laws Of Motion Q.48P
A 5.0-kg bag of potatoes sits on the bottom of a stationary shopping cart. (a) Sketch a free-body diagram for the bag of potatoes. (b) Now suppose the cart moves with a constant velocity. How does this affect your free-body diagram? Explain.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion48ps

Chapter 5 Newton’s Laws Of Motion Q.49P
IP (a) Find the normal force exerted on a 2.9-kg book resting on a surface inclined at 36° above the horizontal. (b) If the angle of the incline is reduced, do you expect the normal force to increase, decrease, or stay the same? Explain.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.50P
IP A gardener mows a lawn with an old-fashioned push mower. The handle of the mower makes an angle of 35° with the surface of the lawn. (a) If a 219-N force is applied along the handle of the 19-kg mower, what is the normal force exerted by the lawn on the mower? (b) If the angle between the surface of the lawn and the handle of the mower is increased, does the normal force exerted by the lawn increase, decrease, or stay the same? Explain.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion50ps

Chapter 5 Newton’s Laws Of Motion Q.51P
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion51p
Solution:

Chapter 5 Newton’s Laws Of Motion Q.52GP
·CE Predict/Explain Riding in an elevator moving upward with constant speed, you begin a game of darts. (a) Do you have to aim your darts higher than, lower than, or the same as when you play darts on solid ground? (b) Choose the best explanation from among the following:
I. The elevator rises during the time it takes for the dart to travel to the darfboard.
II. The elevator moves with constant velocity. Therefore, Newton’s laws apply within the elevator in the same way as on the ground.
III. You have to aim lower to compensate for the upward speed of the elevator.
Solution:
(a) You have to aim your darts same as when you play darts on solid ground.
(b) This is because the elevator is moving with constant velocity. Therefore ’s laws apply within the elevator in the same way as on earth.
Therefore option II is best explanation.

Chapter 5 Newton’s Laws Of Motion Q.53GP
CE Predict/Explain Riding in an elevator moving with a constant upward acceleration, you begin a game of darts. (a) Do you have to aim your darts higher than, lower than, or the same as when you play darts on solid ground? (b) Choose the best explanation from among the following:
I. The elevator accelerates upward, giving its passengers a greater “effective” acceleration of gravity.
II. You have to aim lower to compensate for the upward acceleration of the elevator.
III. Since the elevator moves with a constant acceleration, Newton’s laws apply within the elevator the same as on the ground.
Solution:
In the game of darts a player have to aim and throw the dart on the board to hit the bulls- eye.
(a)
When elevator is going upward with constant acceleration the board hanged on wall of the elevator will also move upward with same acceleration. When a person will throw a dart it will immediately start accelerating downward on the other hand board will keep accelerating upward. Therefore dart will not hit the aimed position. It will hit lower than the aimed position.
Hence in the accelerating elevator a person has to aim his darts higher than the normal.
(b)
When the elevator is accelerating upward then due to force exerted by the floor of the elevator effective acceleration of the passenger increases. Therefore first explanation is right.
As discussed in previous section passenger has aim higher to compensate for the upward acceleration. Therefor second explanation is wrong.
Newton’s law can be applied directly only for inertial reference frame (stationary reference point or moving with constant reference point). Since elevator is moving with constant acceleration therefore newton’s law applied within the elevator is not same as on the ground. Therefore third explanation is wrong
Hence option I is the best explanation.

Chapter 5 Newton’s Laws Of Motion Q.54GP
CE Give the direction of the net force acting on each of the following objects. If the net force is zero, state “zero.” (a) A car accelerating northward from a stoplight. (b) A car traveling southward and slowing down. (c) A car traveling westward with constant speed. (d) A skydiver parachuting downward with constant speed. (e) A baseball during its flight from pitcher to catcher (ignoring air resistance).
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.55GP
·CE Predict/Explain You jump out of an airplane and open your parachute after an extended period of free fall. (a) To decelerate your fall, must the force exerted on you by the parachute be greater than, less than, or equal to your weight? (b) Choose the best explanation from among the following:
I. Parachutes can only exert forces that are less than the weight of the skydiver.
II. The parachute exerts a force exactly equal to the skydiver’s weight.
III. To decelerate after free fall, the net force acting on a skydiver must be upward.
Solution:
(a) To decelerate your fall the force exerted by the parachute must be greater than your weight.
(b) To decelerate after free fall, the net force acting on a sky diver must be upward. This can be achieved only when the force exerted by the parachute is greater than your weight
So option III is the best explanation.

Chapter 5 Newton’s Laws Of Motion Q.56GP
In a tennis serve, a 0.070-kg ball can be accelerated from rest to 36 m/s over a distance of 0.75 m. Find the magnitude of the average force exerted hy the racket on the ball during the serve.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion56gp

Chapter 5 Newton’s Laws Of Motion Q.57GP
A 51.5-kg swimmer with an initial speed of 1.25 m/s decides to coast until she comes to rest. If she slows with constant acceleration and stops after coasting 2.20 m, what was the force exerted on her by the water?
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.58GP
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion58gp
Solution:
The three identical pucks are acted upon by a force of 3N.
F = ma
Since the mass and the force of the 3 pucks are the same, then the acceleration produced by this force must also be the same. The acceleration produced by a force does not depend on the speed of the object, so the acceleration of A, B, and C are all equal.

Chapter 5 Newton’s Laws Of Motion Q.59GP
IP The VASIMR Rocket NASA plans to use a new type of rocket, a Variable Specific Impulse Magnetoplasma Rocket (VASIMR), on future missions. A VASIMR can produce 1200 N of thrust (force) when in operation. If a VASIMR has a mass of 2.2 × 105 kg, (a) what acceleration will it experience? Assume that the only force acting on the rocket is its own thrust, and that the mass of the rocket is constant. (b) Over what distance must the rocket accelerate from rest to achieve a speed of 9500 m/s? (c) When the rocket has covered one-quarter the acceleration distance found in part (b), is its average speed 1/2, 1/3, or 1/4 its average speed during the final three-quarters of the acceleration distance? Explain.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.60GP
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Solution:

Chapter 5 Newton’s Laws Of Motion Q.61GP
At the local grocery store, you push a 14.5-kg shopping cart. You stop for a moment to add a bag of dog food to your cart. With a force of 12.0 N, you now accelerate the cart from rest through a distance of 2.29 m in 3.00 s. What was the mass of the dog food?
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.62GP
· IP BIO The Force of Running Biomechanical research has shown that when a 67-kg person is running, the force exerted oh each foot as it strikes the ground can be as great as 2300 N. (a) What is the ratio of the force exerted on the foot by the ground to the person’s body weight? (b) If the only forces acting on the person are (i) the force exerted by the ground and (ii) the person’s weight, what are the magnitude and direction of the person’s acceleration? (c) If the acceleration found in part (b) acts for 10.0 ms, what is the resulting change in the vertical component of the person’s velocity?
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.63GP
IP BIO Grasshopper Liftoff To become airborne, a 2.0-g grasshopper requires a takeoff speed of 2.7 m/s. It acquires this speed by extending its hind legs through a distance of 3.7 cm. (a) What is the average acceleration of the grasshopper during takeoff? (b) Find the magnitude of the average net force exerted
on the grasshopper by its hind legs during takeoff. (c) If the mass of the grasshopper increases, does the takeoff acceleration increase, decrease, or stay the same? (d) If the mass of the grasshopper increases, does the required takeoff force increase, decrease, or stay the same? Explain.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.64GP
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Chapter 5 Newton’s Laws Of Motion Q.65GP
IP An archer shoots a 0.024-kg arrow at a target with a speed of 54 m/s. When it hits the target, it penetrates to a depth of 0.083 m. (a) What was the average force exerted by the target on the arrow? (b) If the mass of the arrow is doubled, and the force exerted by the target on the arrow remains the same, by what multiplicative factor does the penetration depth change? Explain.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.66GP
An apple of mass m = 0.13 kg falls out of a tree from a height h = 3.2 m. (a) What is the magnitude of the force of gravity, mg, acting on the apple? (b) What is the apple’s speed, v, just before it lands? (c) Show that the force of gravity times the height, mgh, is equal to . (We shall investigate the significance of this result in Chapter 8.) Be sure to show that the dimensions are in agreement as well as the nu-merical values.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.67GP
An apple of mass m = 0.22 kg falls from a tree and hits the ground with a speed of v = 14 m/s. (a) What is the magnitude of the force of gravity, mg, acting on the apple? (b) What is the time, t, required for the apple to reach the ground? (c) Show that the force of gravity times the time, mgt, is equal to mv. (We shall investigate the significance of this result in Chapter 9.) Be sure to show that the dimensions are in agreement as well as the numerical values.
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.68GP
BIO The Fall of T. rex Paleontologists estimate that if a Tyrnnnosaunis rex were to trip and fall, it would have experienced a force of approximately 260,000 N acting on its torso when it hit the ground. Assuming the torso has a mass of 3800 kg, (a) find the magnitude of the torso’s upward acceleration as it comes to rest. (For comparison, humans lose consciousness with an acceleration of about 7g.) (b) Assuming the torso is in free fall for a distance of 1.46 m as it falls to the ground, how much time is required for the torso to come to rest once it contacts the ground?
Solution:
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Chapter 5 Newton’s Laws Of Motion Q.69GP
Deep Space I The NASA spacecraft Deep Space I was shut down on December 18, 2001, following a three-year journey to the asteroid Braille and the comet Borrelly. This spacecraft used a solar-powered ion engine to produce 0.064 ounces of thrust (force) by stripping electrons from neon atoms and accelerating the resulting ions to 70,000 mi/h. The thrust was only as much as the weight of a couple sheets of paper, but the engine operated continuously for 16,000 hours. As a result, the speed of the spacecraft increased by 7900 mi/h. What was the mass of Deep Space I? (Assume that the mass of the neon gas is negligible.)
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion69gps

Chapter 5 Newton’s Laws Of Motion Q.70GP
Your groceries are in a bag with paper handles. The handles will tear off if a force greater than 51.5 N is applied to them. What is the greatest mass of groceries that can be lifted safely with this bag, given that the bag is raised (a) with constant speed, or (b) with an acceleration of 1.25 m/s2?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion70gps

Chapter 5 Newton’s Laws Of Motion Q.71GP
IP While waiting at the airport for your flight to leave, you observe some of the jets as they take off. With your watch you find that it takes about 35 seconds for a plane to go from rest to takeoff speed. In addition, you estimate that the distance re-quired is about 1.5 km. (a) If the mass of a jet is 1.70 × 105 kg, what force is needed for takeoff? (b) Describe the strategy you used to solve part (a).
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion71gps

Chapter 5 Newton’s Laws Of Motion Q.72GP
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion72gp
Solution:

Chapter 5 Newton’s Laws Of Motion Q.73GP
Your groceries are in a bag with paper handles. The handles will tear off if a force greater than 51.5 N is applied to them. What is the greatest mass of groceries that can be lifted safely with this bag, given that the bag is raised (a) with constant speed, or (b) with an acceleration of 1.25 m/s2?
Solution:
The Newton’s second law of motion defined the acceleration of an object produced by a net force is directly proportional to the magnitude of net force and inversely proportional to the mass of object.
The force acting on mass m moves with acceleration a is given as follows:
F=ma
Here, m is the mass and a is the acceleration.
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion73gps

Chapter 5 Newton’s Laws Of Motion Q.74GP
IP Responding to an alarm, a 102-kg fireman slides down a pole to the ground floor, 3.3 m below. The fireman starts at rest and lands with a speed of 4.2 m/s. (a) Find the average force exerted on the fireman by the pole. (b) If the landing speed is half that in part (a), is the average force exerted on the fireman by the pole doubled? Explain. (c) Find the average force exerted on the fireman by the pole when the landing speed is 2.1 m/s.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion74gps

Chapter 5 Newton’s Laws Of Motion Q.75GP
For a birthday gift, you and some friends take a hot-air balloon ride. One friend is late, so the balloon floats a couple of feet off the ground as you wait. Before this person arrives, the combined weight of the basket and people is 1220 kg, and the balloon is neutrally buoyant. When the late arrival climbs up into the basket, the balloon begins to accelerate downward at 0.56 m/s2. What was the mass of the last person to climb aboard?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion75gps

Chapter 5 Newton’s Laws Of Motion Q.76GP
D:\APLUS images\Mastering Physics Solutions Chapter 5 Newton’s Laws Of Motion75gps1.png
Solution:

Chapter 5 Newton’s Laws Of Motion Q.77GP
When two people push in the same direction on an object of mass m they cause an acceleration of magnitude a1. When the same people push in opposite directions, the acceleration of the object has a magnitude a2. Determine the magnitude of the force exerted by each of the two people in terms of m, a1 and a2.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion77gps

Chapter 5 Newton’s Laws Of Motion Q.78GP
· · · An air-track cart of mass m1 = 0.14 kg is moving with a speed v0 = 1.3 m/s to the right when it collides with a cart of mass m2 = 0.25 kg that is at rest. Each cart has a wad of putty on its bumper, and hence they stick together as a result of their collision. Suppose the average contact force between the carts is F = 1.5 N during the collision. (a) What is the acceleration of cart 1? Give direction and magnitude. (b) What is the acceleration of cart 2? Give direction and magnitude. (c) How long does it take for both carts to have the same speed? (Once the carts have the same speed the collision is over and the contact force vanishes.) (d) What is the final speed of the carts, vf? (e) Show that m1v0 is equal to (m1 + m2)vf. (We shall investigate the significance of this result in Chapter 9.)
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion78gps

Chapter 5 Newton’s Laws Of Motion Q.79PP
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion79gp
Solution:

Chapter 5 Newton’s Laws Of Motion Q.80PP
A driver who does not wear a seatbelt continues to move forward with a speed of 18.0 m/s (due to inertia) until something solid like the steering wheel is encountered. The driver now comes to rest in a much shorter distance—perhaps only a few centimeters. Find the magnitude of the net force acting on a 65.0-kg driver who is decelerated from 18.0 m/s to rest in 5.00 cm.
A. 3240 N
B. 1.17 × 104 N
C. 2.11 × 105 N
D. 4.21 × 105 N
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion80pps

Chapter 5 Newton’s Laws Of Motion Q.81PP
Suppose the initial speed of the driver is doubled to 36.0 m/s. If the driver still has a mass of 65.0 kg, and comes to rest in 1.00 m, what is the magnitude of the force exerted on the driver during this collision?
A. 648 N
B. 1170 N
C. 2.11 × 104 N
D. 4.21 × 104 N
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion81pps

Chapter 5 Newton’s Laws Of Motion Q.82PP
If both the speed and stopping distance of a driver are doubled, by what factor does the force exerted on the driver change?
A. 0.5
B. 1
C. 2
D. 4
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion82pps

Chapter 5 Newton’s Laws Of Motion Q.83IP
IP Referring to Example 5-4 Suppose that we would like the contact force between the boxes to have a magnitude of 5.00 N, and that the only thing in the system we are allowed to change is the mass of box 2—the mass of box 1 is 10.0 kg and the applied force is 20.0 N. (a) Should the mass of box 2 be increased or decreased? Explain. (b) Find the mass of box 2 that results in a contact force of magnitude 5.00 N. (c) What is the acceleration of the boxes in this case?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion83ips

Chapter 5 Newton’s Laws Of Motion Q.84IP
Referring to Example 5-4 Suppose the force of 20.0 N pushes on two boxes of unknown mass. We know, however, that the acceleration of the boxes is 1.20 m/s2 and the contact force has a magnitude of 4.45 N. Find the mass of (a) box 1 and (b) box 2.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion84ips

Chapter 5 Newton’s Laws Of Motion Q.85IP
IP Referring to Figure 5-9 Suppose the magnitude of is increased from 41 N to 55 N, and that everything else in the system remains the same. (a) Do you expect the direction of the satellite’s acceleration to be greater than, less than, or equal to 32°? Explain. Find (b) the direction and (c) the magnitude of the satellite’s acceleration in this case.
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion85ips

Chapter 5 Newton’s Laws Of Motion Q.86IP
IP Referring to Figure 5-9 Suppose we would like the acceleration of the satellite to be at an angle of 25°, and that the only quantity we can change in the system is the magnitude of . (a) Should the magnitude of be increased or decreased? Explain. (b) What is the magnitude of the satellite’s acceleration in this case?
Solution:
Mastering Physics Solutions Chapter 5 Newton's Laws Of Motion86ips

Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics

May 21, 2018 by Prasanna

Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics

Mastering Physics Solutions

Chapter 4 Two-Dimensional Kinematics Q.1CQ
What is the acceleration of a projectile when it reaches its highest point? What is its acceleration just before and just after reaching this point?
Solution:
Projectile motion, ignoring air resistance, always acts downward. Thus, during the entire motion projectile, acceleration remains constant.

Chapter 4 Two-Dimensional Kinematics Q.1P
CE Predict/Explain As you walk briskly down the street, you toss a small ball into the air. (a) If you want the ball to land in your hand when it comes back down, should you toss the ball straight upward, in a forward direction, or in a backward direction, relative to your body?
(b) Choose the best explanation from among the following:
I. If the ball is thrown straight up you will leave it behind.
II. You have to throw the ball in the direction you are walking.
III. The ball moves in the forward direction with your walking speed at all times.
Solution:
(a) If you want the ball to land in your hand when it comes back down, you should toss the ball straight upward.
(b) When a person tosses a ball upward while walking, the horizontal component of velocity of the ball and the person will be the same. So the ball moves in the forward direction with your walking speed at all times when you toss the ball straight upwards.
Therefore option III is correct.

Chapter 4 Two-Dimensional Kinematics Q.2CQ
A projectile is launched with an initial speed of v0 at an angle θ above the horizontal. It lands at the same level from which it was launched. What was its average velocity between launch and landing? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics2cqs

Chapter 4 Two-Dimensional Kinematics Q.2P
A sailboat runs before the wind with a constant speed of 4.2 m/s in a direction 32° north of west. How far (a) west and (b) north has the sailboat traveled in 25 min?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics2ps

Chapter 4 Two-Dimensional Kinematics Q.3CQ
A projectile is launched from level ground. When it Sands, its direction of motion has rotated clockwise through 60°. What was the launch angle? Explain.
Solution:
The projectile was launched at an angle of 30°, so its direction of motion has rotated through 60º.

Chapter 4 Two-Dimensional Kinematics Q.3P
As you walk to class with a constant speed of 1.75 m/s, you are moving in a direction that is 18.0° north of east. How much time does it take to change your displacement by (a) 20.0 m east or (b) 30.0 m north?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics3ps

Chapter 4 Two-Dimensional Kinematics Q.4CQ
In a game of baseball, a player hits a high fly ball to the outfield. (a) Is there a point during the flight of the ball where its velocity is parallel to its acceleration? (b) Is there a point where the ball’s velocity is perpendicular to its acceleration? Explain in each case.
Solution:
(a) No, the velocity has two components. The vertical component is tangential to the flight, and the horizontal component is always to the right. Velocity is not parallel to the acceleration in this case.
(b) The ball’s velocity is perpendicular to its acceleration when it is at maximum height.
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics4cqs

Chapter 4 Two-Dimensional Kinematics Q.4P
Starting from rest, a car accelerates at 2.0 m/s2 up a hill that is inclined 5.5° above the horizontal, How far (a) horizontally and (b) vertically has the car traveled in 12 s?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics4ps

Chapter 4 Two-Dimensional Kinematics Q.5CQ

Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics5cqs

Chapter 4 Two-Dimensional Kinematics Q.5P
IP A particle passes through the origin with avelocity of (6.2m/s)ŷ. If the particle’s acceleration is (-4.4m/s2) , (a) what are its x and y positions after 5.0 s? (b) What are vx and uy at this time? (c) Docs the speed of this particle increase with time, decrease with time, or increase and then decrease? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics5ps

Chapter 4 Two-Dimensional Kinematics Q.6CQ
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics6pcq
Solution:

Chapter 4 Two-Dimensional Kinematics Q.6P
An electron in a cathode-ray tube is traveling horizontally at 2.10 × 109 cm/s when deflection plates give it an upward acceleration of 5.30 × 1017 cm/s2. (a) How long does it take for the electron to cover a horizontal distance of 6.20 cm? (b) What is its vertical displacement during this time?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics6ps

Chapter 4 Two-Dimensional Kinematics Q.7CQ
Do projectiles for which air resistance is nonnegligible, such as a bullet fired from a rifle, have maximum range when the launch angle is greater than, less than, or equal to 45°? Explain.
Solution:
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Chapter 4 Two-Dimensional Kinematics Q.7P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics7p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.8CQ
Two projectiles are launched from the same point at the same angle above the horizontal. Projectile 1 reaches a maximum height twice that of projectile 2. What is the ra tio of the initial speed of projectile 1 to the initial speed of projectile 2? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics8cqs

Chapter 4 Two-Dimensional Kinematics Q.8P
CE Predict/Explain Two divers run horizontally off the edge of a low cliff. Diver 2 runs with twice the speed of diver 1. (a) When the divers hit the water, is the horizontal distance covered by diver 2 twice as much, four times as much, or equal to the horizontal distance covered by diver 1? (b) Choose the best explanation from among the following:
I. The drop time is the same for both divers.
II. Drop distance depends on t2.
III. All divers in free fall cover the same distance.
Solution:
(a) The distance horizontal covered by the diver 2 is twice the horizontal distance covered by the diver 1.
(b) As the vertical distance traveled by the two divers is same, also both the divers has zero initial vertical component of velocity, therefore the time of travel for both the divers is same. Therefore diver 2 travels more time than the diver 1.
So option I is correct.

Chapter 4 Two-Dimensional Kinematics Q.9CQ
A child rides on a pony walking with constant velocity. The boy leans over to one side and a scoop of ice cream falls from his ice cream cone. Describe the path of the scoop of ice cream as seen by (a) the child and (b) his parents standing on the ground nearby.
Solution:
(A) The child sees the scoop falling straight downward.
(B) However, the father sees from the ground, that the trajectory of path of scoop is parabolic.

Chapter 4 Two-Dimensional Kinematics Q.9P
CE Predict/Explain Two youngsters dive off an overhang into a lake. Diver 1 drops straight down, and diver 2 runs off the cliff with an initial horizontal speed v0.(a) is the splashdown speed of diver 2 greater than, less than, or equal to the splashdown speed of diver 1? (b) Choose the best explanation from among the following:
I. Both divers are in free fall, and hence they will have the same splashdown speed.
II. The divers have the same vertical speed at splashdown, but diver 2 has the greater horizontal speed.
III. The diver who drops straight down gains more speed than the one who moves horizontally.
Solution:
(a) The splashdown speed of diver 2 is greater than the splash down speed of diver 1.
(b) The divers have same vertical speed at splashdown, but diver 2 has the greater horizontal speed. Therefore the diver 2 has the greater speed than the diver 1.
Therefore option II is the best.

Chapter 4 Two-Dimensional Kinematics Q.10CQ
Drivingdown the highway, you find yourself behind a heavily loaded tomato truck. You follow close behind the truck, keeping the same speed. Suddenly a tomato falls from the back of the truck. Will the tomato hit your car or land on the road, assuming you continue moving with the same speed and direction? Explain.
Solution:
When a tomato suddenly falls from the truck, it will land on the road because the horizontal speed is the same during the entire duration of the fall.

Chapter 4 Two-Dimensional Kinematics Q.10P
An archer shoots an arrow horizontally at a target 15 m away. The arrow is aimed directly at the center of the target, but it hits 52 cm lower. What was the initial speed of the arrow?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics10ps

Chapter 4 Two-Dimensional Kinematics Q.11CQ
A projectile is launched from the origin of a coordinate system where the positive x axis points horizontally to the right and the positive y axis points vertically upward. What was the projectile’s launch angle with respect to the x axis if, at its highest point, its direction of motion has rotated (a) clockwise through 50° or (b) counterclockwise through 30°? Explain.
Solution:
(A) At the highest point, only the horizontal velocity exists. So it is launched from 50º to the positive x-axis.
(B) It is launched from 30º below the negative x-axis.

Chapter 4 Two-Dimensional Kinematics Q.11P
Victoria Falls The great, gray-green, greasy Zambezi River flows over Victoria Falls in south central Africa. The falls are approximately 108 m high. If the river is flowing horizontally at 3.60 m/s just before going over the falls, what is the speed of the water when it hitsthe bottom? Assume the water is in free fall as it drops.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics11ps

Chapter 4 Two-Dimensional Kinematics Q.12P
A diver runs horizontally off the end of a diving board wi th an initial speed of 1.85 m/s. if the diving board is 3.00 m above the water, what is the diver’s speed just before she enters the water?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics12ps

Chapter 4 Two-Dimensional Kinematics Q.13P
An astronaut on the planet Zircon tosses a rock horizontally with a speed of 6.95 m/s. The rock falls through a vertical distance of 1.40 m and lands a horizontal distance of 8.75 m from the astronaut. What is the acceleration of gravity on Zircon?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics13ps

Chapter 4 Two-Dimensional Kinematics Q.14P
IP Pitcher’s Mounds Pitcher’s mounds are raised to compensate for the vertical drop of the ball as it travels a horizontal distance of 18 hi to the catcher, (a) If a pitch is thrown horizontally with an initial speed of 32 m/s, how far does it drop by the time it reaches the catcher? (b) If the speed of the pitch is increased, does the drop distance increase, decrease, or stay the same? Explain, (c) If this baseball game were to be played on the Moon, would the drop distance increase, decrease, or stay the same? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics14ps

Chapter 4 Two-Dimensional Kinematics Q.15P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics15p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.16P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics16p
Solution:

(C) The speed of the clam increases horizontally. However, the vertical velocity won’t change since only g and the time are counted in order to determine y.

Chapter 4 Two-Dimensional Kinematics Q.17P
Amountain climber jumpsa 2.8-m-wide crevasse by leaping horizontally with a speed of 7.8 m/s. (a) If the climber’s direction of motion on landing is -45°, what is the height difference between the two sides of the crevasse? (b) Where does the climber land?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics17ps

Chapter 4 Two-Dimensional Kinematics Q.18P
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Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics18ps

Chapter 4 Two-Dimensional Kinematics Q.19P
IP A white-crowned sparrow flying horizontally with a speed of 1.80 m/s folds its wings and begins to drop in free fall, (a) How far does the sparrow fall after traveling a horizontal distance of 0.500 m? (b) If the sparrow’s initial speed is increased, does the distance of fall increase, decrease, or stay the same?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics19p

Chapter 4 Two-Dimensional Kinematics Q.20P
If, in the previous problem, a jack-o-lantern is given an initial horizontal speed of 3.3 m/s, what are the direction and magnitude of its velocity (a) 0.75 s later, and (b) just before it lands?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics20ps

Chapter 4 Two-Dimensional Kinematics Q.21P
Fairgoers ride a Ferris wheel with a radius of 5.00 m (Figure 4-16). The wheel completes one revolution every 32.0 s. (a) What is the average speed of a rider on this Ferris wheel? (b) If a rider accidentally drops a stuffed animal at the top of the wheel, where does it land relative to the base of the ride? (Note: The bottom of the wheel is 1.75 m above the ground.)
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics21ps

Chapter 4 Two-Dimensional Kinematics Q.22P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics22p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.23P
Baseball and the Washington Monument On August 25, 1894, Chicago catcher William Schriver caught a baseball thrown from the top of the Washington Monument (555 ft, 898 steps), (a) If the ball was thrown horizontally with a speed of 5.00 m/s, where did it land? (b) What were the ball’s speed and direction of motion when caught?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics23ps

Chapter 4 Two-Dimensional Kinematics Q.24P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics24p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.25P
IP A ball rolls off a table and falls 0.75 m to the floor, landing with a speed of 4.0 m/s. (a) What is the acceleration of the ball just before it strikes the ground? (b) What was the initial speed of the ball? (c) What initial speed must the ball have if it is to land with a speed of 5.0 m/s?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics25ps

Chapter 4 Two-Dimensional Kinematics Q.26P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics26p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.27P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics27p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.28P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics28p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.29P
A second baseman tosses the ball to the first baseman, who catches it at the same level from which it was thrown. The throw is made with an initial speed of 18.0 m/s at an angle of 37.5° above the horizontal, (a) What is the horizontal component of the ball’s velocity just before it is caught? (b) How long is the ball in the air?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics29ps

Chapter 4 Two-Dimensional Kinematics Q.30P
Referring to the previous problem, what are the y component of the ball’s velocity and its direction of motion just before it is caught?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics30ps

Chapter 4 Two-Dimensional Kinematics Q.31P
A cork shoots out of a champagne bottle at an angle of 35.0° above the horizontal. If the cork travels a horizontal distance of 1.30 m in 1.25s, what was its initial speed?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics31ps

Chapter 4 Two-Dimensional Kinematics Q.32P
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Solution:

Chapter 4 Two-Dimensional Kinematics Q.33P
In a game of basketball, a forward makes a bounce pass to the center. The ball is thrown with an initial speed of 4.3 m/s at an angle of 15° below the horizontal. Tt is released 0.80 m above the floor. What horizontal distance does the ball cover before bouncing?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics33ps

Chapter 4 Two-Dimensional Kinematics Q.34P
Repeat the previous problem for a bounce pass in which the ball is thrown 15° above the horizontal.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics34ps

Chapter 4 Two-Dimensional Kinematics Q.35P
IP Snowballs are thrown with a speed of 13 m/s from a roof 7.0 m above the ground. Snowball A is thrown straight down-
ward; snowball B is thrown in a direction 25° above the horizontal, (a) Is the landing speed of snowball A greater than, less than, or the same as the landing speed of snowball B? Explain. (b) Verify your answer to part (a) by calculating the landing speed of both snowballs.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics35ps

Chapter 4 Two-Dimensional Kinematics Q.36P
In the previous problem, find the direction of motion of the two snowballs just before they land.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics36ps

Chapter 4 Two-Dimensional Kinematics Q.37P
A golfer gives a ball a maximum initial speed of 34.4 m/s. (a) What is the longest possible hole-irt-one for this golfer? Neglect any distance the ball might roll on the green and assume that the tee and the green are at the same level, (b) What is the minimum speed of the ball during this hole-in-one shot?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics37ps

Chapter 4 Two-Dimensional Kinematics Q.38P
What is the highest tree the ball in the previous problem could clear on its way to the longest possible holc-in-one?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics38ps

Chapter 4 Two-Dimensional Kinematics Q.39P
The “hang time” of a punt is measured to be 4.50 s. If the ball was kicked at an angle of 63.0° above the horizontal and was caught at the same level from which it was kicked, what was its initial speed?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics39ps

Chapter 4 Two-Dimensional Kinematics Q.40P
In a friendly game of handball, you hit the ball essentially at ground level and send it toward the wall with a speed of 18 m/s at an angle of 32° above the horizontal, (a) How long does it take for the ball to reach the wall if it is 3.8 m away? (b) How high is the ball when it hits the wall?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics40ps

Chapter 4 Two-Dimensional Kinematics Q.41P
IP Tn the previous problem, (a) what are the magnitude and direction of the ball’s velocity when it stilkes the wall? (b) Has the ball reached the highest point of its trajectory at this time? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics41ps

Chapter 4 Two-Dimensional Kinematics Q.42P
A passenger on the Ferris wheel described in Problem 21 drops his keys when he is on the way up and at the 10 o’clock position. Where do the keys land relative to thebase of the ride?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics42ps

Chapter 4 Two-Dimensional Kinematics Q.43P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics43p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.44P
A certain projectile is launched with an initial speed v0. At its highest point its speed is v0/4- What was the launch angle?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics44p

Chapter 4 Two-Dimensional Kinematics Q.45P
Punkin Chunkin In Sussex County, Delaware, a post-Halloween tradition is “Punkin Chunkin,” in which contestants build cannons, catapults, trebuchets, and other devices to launch pumpkins and compete for the greatest distance. Though hard to believe, pumpkins have been projected a distance of 4086 feet in this contest. What is the mnirmum initial speed needed for such a shot?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics45ps

Chapter 4 Two-Dimensional Kinematics Q.46P
A dolphin jumps with an initial velocity of 12.0 m/s at an angle of 40.0° above the horizontal. The dolphin passes through the center of a hoop before returning to the water. If the dolphin is moving horizontally when it goes through the hoop, how high above the water is the center of the hoop?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics46ps

Chapter 4 Two-Dimensional Kinematics Q.47P
A player passes a basketball to another player who catches it at the same level from which it was thrown. The initial speed of the ball is 7.1 m/s, and it travels a distance of 4.6 m. What were (a) the initial direction of the ball and (b) its time of flight?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics47ps

Chapter 4 Two-Dimensional Kinematics Q.48P
A golf ball is struck with a five iron on level ground. It lands 92.2 m away 4.30 s later. What were (a) the direction and (b) the magnitude of the initial velocity?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics48ps

Chapter 4 Two-Dimensional Kinematics Q.49P
A Record Toss Babe Didrikson holds the world record for the longest baseball throw (296 ft) by a woman. For the following questions, assume that the ball was thrown at an angle of 45.0° above the horizontal, that it traveled a horizontal distance of 296 ft, and that it was caught at the same level from which it was thrown, (a) What was the ball’s initial speed? (b) How long was the ball in the air?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics49ps

Chapter 4 Two-Dimensional Kinematics Q.50P
In the photograph to the left on page 87, suppose the cart that launches the ball is 11 cm high. Estimate (a) the launch speed of the ball and (b) the time interval between successive stroboscopic exposures.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics50ps

Chapter 4 Two-Dimensional Kinematics Q.51P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics51p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.52P
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics52p
Solution:

Chapter 4 Two-Dimensional Kinematics Q.53P
IP A soccer ball is kicked with an initial speed of 10.2 m/s in a direction 25.0° above the horizontal. Find the magnitude and direction of its velocity (a) 0.250 s and (b) 0.500 s after being kicked, (c) is the ball at its greatest height before or after 0.500 s? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics53ps

Chapter 4 Two-Dimensional Kinematics Q.54P
A second soccer ball is kicked with the same initial speed as in Problem 53. After 0.750 s it is at its highest point. What was its initial direction of motion?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics54ps

Chapter 4 Two-Dimensional Kinematics Q.55P
IP A golfer tees off on level ground, giving the ball an initial speed of 46.5 m/s and an initial direction of 37.5° above the horizontal, (a) How far from the golfer does the ball land? (b) The next golfer in the group hits a ball with the same initial speed but at an angle above the horizontal that is greater than 45.0°. Tf the second ball travels the same horizontal distance as the first ball, what was its initial direction of motion? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics55ps

Chapter 4 Two-Dimensional Kinematics Q.56P
IP One of the most popular events at Highland games is the hay toss, where competitors use a pitchfork to throw a bale of hay over a raised bar. Suppose the initial velocity of a bale of hay is . (a) After what minimum time is its speed equal to 5,00 m/s? (b) How long after the hay is tossed is it moving in a direction that is 45.0° below the horizontal? (c) If the bale of hay is tossed with the same initial speed, only this time straight upward, will its time in the air increase, decrease, or stay the same? Explain.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics56ps

Chapter 4 Two-Dimensional Kinematics Q.57GP
CE Child 1 throws a snowball horizontally from the top of a roof; child 2 throws a snowball straight down. Once in flight, is the acceleration of snowball 2 greater than, less than, or equal to the acceleration of snowball 1?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics57gps

Chapter 4 Two-Dimensional Kinematics Q.58GP
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics58gp
Solution:
The penguin lands at an elevation that is above the water then the speed of the penguin gets decreased before it lands on the ice.
For a projectile initial and final point will be on the same level therefore velocity remains the same where as in the case of penguins jump from water to ice levels are different the speed before it land on ice becomes less.

Chapter 4 Two-Dimensional Kinematics Q.59GP
CE Predict/Explain A person flips a coin into the air and it lands on the ground a few feet away, (a) If the person were to perform an identical coin flip on an elevator rising with constant speed, would the coin’s time of flight be greater than, less than, or equal to its time of flight when the person was at rest? (b) Choose the best explanation from among the following:
I. The floor of the elevator is moving upward, and hence it catches up with the coin in mid flight.
II. The coin has the same upward speed as the elevator when it is tossed, and the elevator’s speed doesn’t change during the coin’s flight.
III. The coin starts off with a greater upward speed because of the elevator, and hence it reaches a greater height.
Solution:
(a) The time of flight of the coin in the lift moving up with constant speed is same as the time of flight on ground.
(b) This is because of the coin has the same upward speed as the elevator when it is tossed, and the elevator’s speed doesn’t change during the coin’s flight.
So option II is the best explanation.

Chapter 4 Two-Dimensional Kinematics Q.60GP
CEPredict/Explain Suppose the elevator in the previous problem is rising with a constant upward acceleration, rather than constant velocity, (a) In this case, would the coin’s time of flight be greater than, less than, or equal to its time of flight when the person was at rest? (b) Choose the best explanation from among the following:
I. The coin has the same acceleration once it is tossed, whether the elevator accelerates or not.
II. The elevator’s upward speed increases during the coin’s flight, and hence it catches up with the coin at a greater height than before.
III. The coin’s downward acceleration is less than before because the elevator’s upward acceleration partially cancels it.
Solution:
(a) The time of flight of the coin in the lift moving up with constant acceleration is less than the time of flight on ground.
(b) In this case the coin will have greater acceleration relative to the floor of the elevator. Or the elevator’s upward speed increases during the coin’s flight, and hence it catches up with the coin at greater height than before. So, the option II is the best explanation.

Chapter 4 Two-Dimensional Kinematics Q.61GP
A train moving with constant velocity travels 1.70 m north in 12 s and an undetermined, distance to the west. The speed of the train is 32 m/s. (a) Find the direction of the train’s motion relative to north, (b) How far west has the train traveled in this time?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics61gps

Chapter 4 Two-Dimensional Kinematics Q.62GP
Referring to Example 4-2, find (a) the x component and (b) the y component of the hummingbird’s velocity at the time t = 0.72 s. (c) What is the bird’s direction of travel at this time, relative to the positive x axis?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics62gps

Chapter 4 Two-Dimensional Kinematics Q.63GP
A racket ball is struck in such a way that it leaves the racket with a speed of 4.87 m/s in the horizontal direction. When the ball hits the court, it is a horizontal distance of 1.95 m from the racket. Find the height of the racket ball when it left the racket.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics63gps

Chapter 4 Two-Dimensional Kinematics Q.64GP
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics64gp
Solution:

Chapter 4 Two-Dimensional Kinematics Q.65GP
Repeat the previous problem, this time assuming that the balloon is descending with a speed of 2.00 m/s.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics65gps

Chapter 4 Two-Dimensional Kinematics Q.66GP
IP A soccer ball is kicked from the ground with an initial speed of 14.0 m/s. After 0.275 s its speed is 12.9 m/s. (a) Give a strategy that will allow you to calculate the ball’s initial direction of motion, (b) Use your strategy to find the initial direction.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics66gps

Chapter 4 Two-Dimensional Kinematics Q.67GP
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics67gp
Solution:

Chapter 4 Two-Dimensional Kinematics Q.68GP
When the dried-up seed pod of a scotch broom plant bursts open, it shoots out a seed with an initial velocity of 2.62 m/s at an angle of 60.5° above the horizontal. If the seed pod is 0.455 m above the ground, (a) bow long does it take for the seed to land? (b) What horizontal distance does it cover during its flight?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics68gps

Chapter 4 Two-Dimensional Kinematics Q.69GP
Referring to Problem 68, a second seed shoots out from the pod with the same speed but with a direction of motion 30.0° below the horizontal, (a) How long does it take for the second seed to land? (b) What horizontal distance does it cover during its flight?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics69gps

Chapter 4 Two-Dimensional Kinematics Q.70GP
A shot-putter throws the shot with an initial speed of 12.2 m/s from a height of 5.15 ft above the ground. What is the range of the shot if the launch angle is (a) 20.0°, (b) 30.0°, or (c) 40.0°?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics70gps

Chapter 4 Two-Dimensional Kinematics Q.71GP
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics71gp
Solution:

Chapter 4 Two-Dimensional Kinematics Q.72GP
Aball thrown straight upward returns to its original level in 2.75 s. A second ball is thrown at an angle of 40.0° above the horizontal. What is the initial speed of the second ball if it also returns to its original level in 2.75 s?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics72gps

Chapter 4 Two-Dimensional Kinematics Q.73GP
IP A cannon is placed at the bottom of a cliff 61.5 m high. If the cannon is fired straight upward, the cannonball just reaches the top of the cliff, (a) What is the initial speed of the cannonball? (b) Suppose a second cannon is placed at the top of the cliff. This cannon is fired horizontally, giving its cannonbails the same initial speed found in part(a). Show that the range of this cannon is the same as the maximum range of the cannon at the base of the cliff. (Assume the ground at the base of the cliff is level, though the result is valid even if the ground is not level.)
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics73gp

Chapter 4 Two-Dimensional Kinematics Q.74GP
IP A cannon is placed at the bottom of a cliff 61.5 m high. If the cannon is fired straight upward, the cannonball just reaches the top of the cliff, (a) What is the initial speed of the cannonball? (b) Suppose a second cannon is placed at the top of the cliff. This cannon is fired horizontally, giving its cannonbails the same initial speed found in part(a). Show that the range of this cannon is the same as the maximum range of the cannon at the base of the cliff. (Assume the ground at the base of the cliff is level, though the result is valid even if the ground is not level.)Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics74gps

Chapter 4 Two-Dimensional Kinematics Q.75GP
Sliot Put Record The men’s world record for the shot put, 23.12 in, was set by Randy Barnes of the United States on May 20,1990. If the shot was launched from 6.00 ft above the ground at an initial angle of 42.0°, what was its initial speed?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics75gps

Chapter 4 Two-Dimensional Kinematics Q.76GP
Referring to Conceptual Checkpoint 4-3, suppose the two snowballs are thrown from an elevation of 15 m with an initial speed of 12 m/s. What is the speed of each ball when it is 5.0 m above the ground?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics76gps

Chapter 4 Two-Dimensional Kinematics Q.77GP
IP A hockey puck just clears the 2.00-m-high boards on its way out of the rink. The base of the boards is 20.2 m from the pqint where the puck is launched, (a) Given the launch angle of the puck, θ, outline a strategy that you can use to find its initial speed, u0 (b) Use your strategy to find u0 for 0 = 15.0°.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics77gps

Chapter 4 Two-Dimensional Kinematics Q.78GP
Referring to Active Example 4-2, suppose the ball is punted from an initial height of 0.750 m. What is the initial speed of the ball in this case?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics78gps

Chapter 4 Two-Dimensional Kinematics Q.79GP
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Solution:

Chapter 4 Two-Dimensional Kinematics Q.80GP
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Solution:

Chapter 4 Two-Dimensional Kinematics Q.81GP
As discussed in Example 4-7, the archcrfish hunts by dislodging an unsuspecting insect from its resting place with a stream of water expelled from the fish’s mouth. Suppose the archerfish squirts water with a speed of 2.15 m/s at an angle of 52.0° above the horizontal, and aims for a beetle on a leaf 3.00 cm above the water’s surface, (a) At what horizontal distance from the beetle should the archerfish fire if it is to hit its target in the least time? (b) How much time will the beetle have to react?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics81gps

Chapter 4 Two-Dimensional Kinematics Q.82GP
(a) What is the greatest horizontal distance from which the archerfish can hit the beetle, assuming the same squirt speed and direction as in Problem 81? (b) How much time docs the beetle have to react in this case?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics82gps

Chapter 4 Two-Dimensional Kinematics Q.83GP
Find the launch angle for which the range and maximum height of a projectile are the same.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics83gps

Chapter 4 Two-Dimensional Kinematics Q.84GP
A mountain climber jumps a crevasse of width W by leaping horizontally with speed u0.(a) if the height difference between the two sides of the crevasse is h, what is the minimum value of u0 for the climber to land safely on the other side? (b) In this case, what is the cumber’s direction of motion on landing?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics84gps

Chapter 4 Two-Dimensional Kinematics Q.85GP
Prove that the landing speed of a projectile is independent of launch angle for a given height of launch.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics85gps

Chapter 4 Two-Dimensional Kinematics Q.86GP
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics86gp
Solution:

Chapter 4 Two-Dimensional Kinematics Q.87GP
Landing on a Different Level A projectile fired from y = 0 with initial speed u0 e:\04-02-2016\chapter 4\1403\9781111788452\exercisesand initial angle θ lands on a different level, y = h. Show that the time of flight of the projectile is where T0 is the time of flight for h = 0 and H is the maximum height of the projectile.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics87gps

Chapter 4 Two-Dimensional Kinematics Q.88GP
A mountain climber jumps a crevasse by leaping horizontally with speed u0. If the climber’s direction of motion on landing is θ below the horizontal, what is the height difference h between the two sides of the crevasse?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics88gps

Chapter 4 Two-Dimensional Kinematics Q.89GP
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Solution:

Chapter 4 Two-Dimensional Kinematics Q.90GP
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Solution:

Chapter 4 Two-Dimensional Kinematics Q.91PP
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics91gp
Solution:

Chapter 4 Two-Dimensional Kinematics Q.92PP
How much time elapses between the first and second bounces?
A. 1.38 s
B. 2.58 s
C. 5.15 s
D. 5.33 s
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics92gps

Chapter 4 Two-Dimensional Kinematics Q.93PP
How far does a rover travel in the horizontal direction between its first and second bounces?
A. 13.2 m
B. 49.4 m
C. 51.1m
D. 98.7 m
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics93pps

Chapter 4 Two-Dimensional Kinematics Q.94PP
What is the average velocity of a rover between its first and second bounces?
A. 0
B. 2.57 m/s in the x direction
C. 9.92 m/s at 75.0° above the x axis
D. 9.58 m/s in the y direction
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics94pps

Chapter 4 Two-Dimensional Kinematics Q.95IP
Referring to Example 4-5 (a) At what launch angle greater than 54.0° does the golf ball just barely miss the top of the tree in front of the green? Assume the ball has an initial speed of 13.5 m/s, and thatthe tree is 3.00 m high and is a horizontal distance of 14.0 m from the launch point, (b) Where does the ball land in the case described in part (a)? (c) At what launch angle less than 54.0° does the golf ball just barely miss the top of the tree in front of the green? (d) Where does the ball land in the case described in part (c)?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics95ips

Chapter 4 Two-Dimensional Kinematics Q.96IP
Referring to Example 4-5 Suppose that the golf ball is launched with a speed of 15.0 m/s at an angle of 57.5° above the horizontal, and that it lands on a green 3.50 m above the level where it was struck, (a) What horizontal distance does the ball cover during its flight? (b) What increase in initial speed would be needed to increase the horizontal distance in part (a) by 7.50 m? Assume everything else remains the same.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics96ips

Chapter 4 Two-Dimensional Kinematics Q.97IP
Referring to Example 4-6 Suppose the ball is dropped at the horizontal distance of 5.50 m, but from a new height of 5.00 m. The dolphin jumps with the same speed of 12.0 m/s. (a) What launch angle must the dolphin have if it is to catch the ball? (b) At what height does the dolphin catch the ball in this case? (c) What is the minimum initial speed the dolphin must have to catch the ball before it hits the water?
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics97ips

Chapter 4 Two-Dimensional Kinematics Q.98IP
IP Referring to Example 4-6 Suppose we change the dolphin’s launch angle to 45.0°, but everything else remains the same. Thus, the horizontal distance to the ball is 5.50 m, the drop height is 4.10 m, and the dolphin’s launch speed is 12.0 m/s. (a) What is the vertical distance between the dolphin and the ball when the dolphin reaches the horizontal position of the ball? We refer to this as the “miss distance.” (b) If the dolphin’s launch speed is reduced, will the miss distance increase, decrease, or stay the same? (c) Find the miss distance for a launch speed of 10.0 m/s.
Solution:
Mastering Physics Solutions Chapter 4 Two-Dimensional Kinematics98ips

Mastering Physics Solutions Chapter 3 Vectors In Physics

May 18, 2018May 17, 2018 by Prasanna

Mastering Physics Solutions Chapter 3 Vectors In Physics

Mastering Physics Solutions

Chapter 3 Vectors In Physics Q.1CQ
For the following quantities, indicate which is a scalar and which is a vector: (a) the time it takes for you to run the 100-yard dash; (b) your displacement after running the 100-yard dash; (c) your average velocity while running; (d) your average speed while running.
Solution:
(A) Scalar, since there is no direction.
(B) Vector, since displacement depends on the direction.
(C) Vector, since velocity is a vector quantity.
(D) Scalar, since speed is a scalar quantity.

Chapter 3 Vectors In Physics Q.1P
Suppose that the component of a certain vector is doubled, (a) By what multiplicative factor docs the magnitude of the vector change? (b) By what multiplicative factor does the direction angle of the vector change?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics1p

Chapter 3 Vectors In Physics Q.2CQ
Mastering Physics Solutions Chapter 3 Vectors In Physics2cq
Solution:

Chapter 3 Vectors In Physics Q.2P
Mastering Physics Solutions Chapter 3 Vectors In Physics2p
Solution:
CONCEPT:
The physical quantity which has both magnitude and direction is called as vector quantity. It is represented by an arrow such that the length of the arrow is proportional to the magnitude of the physical quantity and the arrow head is pointed in the given direction.
Mastering Physics Solutions Chapter 3 Vectors In Physics2psol

Chapter 3 Vectors In Physics Q.3CQ

Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics3cqsol

Chapter 3 Vectors In Physics Q.3P
Mastering Physics Solutions Chapter 3 Vectors In Physics3p
Solution:

Chapter 3 Vectors In Physics Q.4CQ
Can a component of a vector be greater than the vector’s magnitude?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics4cq

Chapter 3 Vectors In Physics Q.4P
Mastering Physics Solutions Chapter 3 Vectors In Physics4p
Solution:

Chapter 3 Vectors In Physics Q.5CQ

Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics5cqsol

Chapter 3 Vectors In Physics Q.5P
The press box at a baseball park is 32.0 ft above the ground. A reporter in the press box looks at an angle of 15.0° below the horizontal to see second base. What is the horizontal distance from the press box to second base?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics5p

Chapter 3 Vectors In Physics Q.6CQ
Can a vector with zero magnitude have one or more components that are nonzero? Explain.
Solution:
No, if a vector has a non-zero component, the smallest magnitude it can have is the magnitude of the component.

Chapter 3 Vectors In Physics Q.6P
You are driving up a long, inclined road. After 1.2 miles you notice that signs along the roadside indicate that your elevation has increased by 530 ft. (a) What is the angle of the road above the horizontal? (b) How far do you have to drive to gam an additional 150 ft of elevation?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics6p

Chapter 3 Vectors In Physics Q.7CQ
Mastering Physics Solutions Chapter 3 Vectors In Physics7cq
Solution:

Chapter 3 Vectors In Physics Q.7P
A One-Percent Grade A road that rises 1 ft for every 100 ft traveled horizontally is said to have a 1 % grade. Portions of the Lewiston grade, near Lewiston, Idaho, have a 6% grade. At what angle is this road inclined above the horizontal?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics7p

Chapter 3 Vectors In Physics Q.8CQ

Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics8cqsol

Chapter 3 Vectors In Physics Q.8P
Find the x and y components of a position vector of magnitude r = 75 m, if its angle relative to the x axis is (a) 35.0° and (b) 65.0°.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics8p

Chapter 3 Vectors In Physics Q.9CQ

Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics9cqsol

Chapter 3 Vectors In Physics Q.9P
A baseball “diamond” (Figure) is a square with sides 90 ft in length. If the positive x axis points from home plate to first base, and the positive y axis points from home plate to third base, find the displacement vector of a base runner who has just hit (a) a double, (b) a triple, or (c) a home run.
Mastering Physics Solutions Chapter 3 Vectors In Physics9p
Solution:

Chapter 3 Vectors In Physics Q.10CQ

Solution:

Chapter 3 Vectors In Physics Q.10P
A lighthouse that rises 49 ft above the surface of the water sits on a rocky cliff that extends 19 ft from its base, as shown in Figure. A sailor on the deck of a ship sights the top of the lighthouse at an angle of 30.0° above the horizontal. If the sailor’s eye level is 14 ft above the water, how far is the ship from the rocks?
Mastering Physics Solutions Chapter 3 Vectors In Physics10p
Solution:

Chapter 3 Vectors In Physics Q.11CQ

Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics11cqsol

Chapter 3 Vectors In Physics Q.11P
H2 O A water molecule is shown schematically in Figure. The distance from the center of the oxygen atom to the center of a hydrogen atom is 0.96 Å, and the angle between the hydrogen atoms is 1.04.5°. Find the center-to-center distance between the hydrogen atoms. (1 Å = 10-10 m.)
Mastering Physics Solutions Chapter 3 Vectors In Physics11p
Solution:

Chapter 3 Vectors In Physics Q.12CQ
Use a sketch to show that two vectors of unequal magnitude cannot add to zero, but that three vectors of unequal magnitude can.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics12cq

Chapter 3 Vectors In Physics Q.12
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Solution:

Chapter 3 Vectors In Physics Q.13CQ
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Solution:

Chapter 3 Vectors In Physics Q.13P
Rain is failing vertically downward and you are running for shelter. To keep driest, should you hold your umbrella vertically, tilted forward, or tilted backward? Explain.
Solution:
To keep the driest, tilt the umbrella forward and let it point in the direction opposite to the direction of the rain’s velocity in reference to you.

Chapter 3 Vectors In Physics Q.14CQ
When sailing, the wind feels stronger when you sail upwind (“beating”) than when you are sailing downwind (“running”). Explain.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics14cq

Chapter 3 Vectors In Physics Q.14P
You drive a car 680 ft to the east, then 340 ft to the north. (a) What is the magnitude of your displacement? (b) Using a sketch, estimate the direction of your displacement, (c) Verify your estimate in part (b) with a numerical calculation of the direction.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics14p

Chapter 3 Vectors In Physics Q.15P
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Solution:

Chapter 3 Vectors In Physics Q.16P
A treasure map directs you to start at a palm tree and walk due north for 15.0 m. You are then to turn 90° and walk 22.0 m; then turn 90° again and walk 5.00 m. Give the distance from the palm tree, and the direction relative to north, for the of the four possible locations of the treasure.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics16p

Chapter 3 Vectors In Physics Q.17P
A whale comes to the surface to breathe and then dives at an angle of 20.0° below the horizontal (Figure). If the whale continues in a straight line for 150 m, (a) how deep is it, and (b) how far has it traveled horizontally?
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Solution:

Chapter 3 Vectors In Physics Q.18P
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Chapter 3 Vectors In Physics Q.19P
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Chapter 3 Vectors In Physics Q.20P
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Chapter 3 Vectors In Physics Q.21P
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Chapter 3 Vectors In Physics Q.22P
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Chapter 3 Vectors In Physics Q.23P
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Chapter 3 Vectors In Physics Q.24P
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Chapter 3 Vectors In Physics Q.25P
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Chapter 3 Vectors In Physics Q.26P
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Chapter 3 Vectors In Physics Q.27P
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Chapter 3 Vectors In Physics Q.28P
A vector has a magnitude of 3.50 m and points in a direction that is 145° counterclockwise from the x axis. Find the x and y components of this vector.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics28p

Chapter 3 Vectors In Physics Q.29P
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Chapter 3 Vectors In Physics Q.30P
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Chapter 3 Vectors In Physics Q.31P
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Chapter 3 Vectors In Physics Q.35P
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Chapter 3 Vectors In Physics Q.36P
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Chapter 3 Vectors In Physics Q.37P
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Chapter 3 Vectors In Physics Q.38P
In its daily prowl of the neighborhood, a cat makes a displacement of 120 m due north, followed by a 72-m displacement due west, (a) Find the magnitude and direction of the displacement required for the cat to return home, (b) If, instead, the cat had first prowled 72 m west and then 120 m north, how would this affect the displacement needed to bring it home? Explain.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics38p

Chapter 3 Vectors In Physics Q.39P
If the cat in Problem takes 45 minutes to complete the 120-m displacement and 17 minutes to complete the 72-m displacement, what arc the magnitude and direction of its average velocity during this 62-minute period of time?
In its daily prowl of the neighborhood, a cat makes a displacement of 120 m due north, followed by a 72-m displacement due west, (a) Find the magnitude and direction of the displacement required for the cat to return home, (b) If, instead, the cat had first prowled 72 m west and then 120 m north, how would this affect the displacement needed to bring it home? Explain.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics39p

Chapter 3 Vectors In Physics Q.40P
What are the direction and magnitude of your total displacement if you have traveled due west with a speed of 27 m/s for 125 s, their due south at 14 m/s for 66 s?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics40p

Chapter 3 Vectors In Physics Q.41P
You drive a car 1500 ft to the east, then 2500 ft to the north. If the trip took 3.0 minutes, what were the direction and magnitude of your average velocity?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics41p

Chapter 3 Vectors In Physics Q.42P
A jogger runs with a speed of 3.25 m/s in a direction 30.0° above the x axis, (a) Find the x and y components of the jogger’s velocity, (b) How will the velocity components found in part (a) change if the jogger’s speed is halved?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics42p

Chapter 3 Vectors In Physics Q.43P
You throw a ball upward with an initial speed of 4.5 m/s. When it returns to your hand 0.92 s later, it has the same speed in the downward direction (assuming air resistance can be ignored). What was the average acceleration vector of the ball?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics43p

Chapter 3 Vectors In Physics Q.44P
A skateboarder rolls from rest down an inclined ramp that is 15.0 m long and inclined above the horizontal at an angle of θ = 20.0°. When she reaches the bottom of the ramp 3.00 s later her speed is 10.0 m/s. Show that the average acceleration of the skateboarder is g sin θ, where g = 9.81 m/s2.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics44p

Chapter 3 Vectors In Physics Q.45P
Consider a skateboarder who starts from rest at the top of a ramp that is inclined at an angle of 17.5° to the horizontal. Assuming that the skateboarder’s acceleration is g sin 17.5°, Find his speed when he reaches the bottom of the ramp in 3.25 s.
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Mastering Physics Solutions Chapter 3 Vectors In Physics45p

Chapter 3 Vectors In Physics Q.46P
Mastering Physics Solutions Chapter 3 Vectors In Physics46p
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Chapter 3 Vectors In Physics Q.47P
Mastering Physics Solutions Chapter 3 Vectors In Physics47p
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Chapter 3 Vectors In Physics Q.48P
Mastering Physics Solutions Chapter 3 Vectors In Physics48p
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Chapter 3 Vectors In Physics Q.49P
As an airplane taxies on the runway with a speed of 16.5 m/s, a Flight attendant walks toward the tail of the plane with a speed of 1.22 m/s. What is the flight attendant’s speed relative to the ground?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics49p

Chapter 3 Vectors In Physics Q.50P
Referring to part (a) of Example, find the time it takes for the boat to reach the opposite shore if the river is 35 m wide.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics50p

Chapter 3 Vectors In Physics Q.51P
As you hurry to catch your flight at the local airport, you encounter a moving walkway that is 85 m long and has a speed of 2.2 m/s relative to the ground. If it takes you 68 s to cover 85 m when walking on the ground, how long will it take you to cover the same distance on the walkway? Assume that you walk with the same speed on the walkway as you do on the ground.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics51p

Chapter 3 Vectors In Physics Q.52P
In Problem, how long would it take you to cover the 85-m length of the walkway if, once you get on the walkway, you immediately turn around and start walking in the opposite direction with a speed of 1.3 m/s relative to the walkway?
As you hurry to catch your flight at the local airport, you encounter a moving walkway that is 85 m long and has a speed of 2.2 m/s relative to the ground. If it takes you 68 s to cover 85 m when walking on the ground, how long will it take you to cover the same distance on the walkway? Assume that you walk with the same speed on the walkway as you do on the ground.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics52p

Chapter 3 Vectors In Physics Q.53P
The pilot of an airplane wishes to fly due north, but there is a 65-km/h wind blowing toward the east, (a) In what direction should the pilot head her plane if its speed relative to the air is 340 km/h? (b) Draw a vector diagram that illustrates your result in part (a), (c) If the pilot decreases the air speed of the plane, but still wants to head due north, should the angle found in part (a) be increased or decreased?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics53p

Chapter 3 Vectors In Physics Q.54P
A passenger walks from one side of a ferry to the other as it approaches a dock. If the passenger’s velocity is 1.50 m/s due north relative to the ferry, and 4.50 m/s at an angle of 30.0° west of north relative to the water, what are the direction and magnitude of the Ferry’s velocity relative to the water?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics54p

Chapter 3 Vectors In Physics Q.55P
You are riding on a Jet Ski at an angle of 35° upstream, on a river flowing with a speed of 2.8 m/s. If your velocity relative to the ground is 9.5 m/s at an angle of 20.0° upstream, what is the speed of the Jet Ski relative to the water? (Note: Angles are measured relative to the x axis shown in Example.)
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics55p

Chapter 3 Vectors In Physics Q.56P
In Problem, suppose the Jet Ski is moving at a speed of 12 m/s relative to the water, (a) At what angle must you point the Jet Ski if your velocity relative to the ground is to be perpendicular to the shore of the river? (b) If you increase the speed of the Jet Ski relative to the water, does the angle in part (a) increase, decrease, or stay the same? Explain. (Note: Angles are measured relative to the x axis shown, in Example.)
You are riding on a Jet Ski at an angle of 35° upstream, on a river flowing with a speed of 2.8 m/s. If your velocity relative to the ground is 9.5 m/s at an angle of 20.0° upstream, what is the speed of the Jet Ski relative to the water? (Note: Angles are measured relative to the x axis shown in Example.)
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics56p

Chapter 3 Vectors In Physics Q.57P
Two people take identical Jet Skis across a river, traveling at the same speed relative to the water. Jet Ski A heads directly across the river and is carried downstream by the current before teaching the opposite shore. Jet Ski B travels in a direction that is 35° upstream and arrives at the opposite shore directly across from the starting point, (a) Which Jet Ski reaches the opposite shore in the least amount of time? (b) Confirm your answer to part (a) by finding the ratio of the time it takes for the two Jet Skis to cross the river. (Note: Angles are measured relative to the x axis shown in Example.)
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics57p

Chapter 3 Vectors In Physics Q.58GP
Mastering Physics Solutions Chapter 3 Vectors In Physics58p
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Chapter 3 Vectors In Physics Q.59GP
Mastering Physics Solutions Chapter 3 Vectors In Physics59p
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Chapter 3 Vectors In Physics Q.60GP
You slide a box up a loading ramp that is 10.0 ft long. At the top of the ramp the box has risen a height of 3.00 ft. What is the angle of the ramp above the horizontal?
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Chapter 3 Vectors In Physics Q.61GP
Mastering Physics Solutions Chapter 3 Vectors In Physics61p
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Chapter 3 Vectors In Physics Q.62GP
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Chapter 3 Vectors In Physics Q.63GP
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Chapter 3 Vectors In Physics Q.64GP
Mastering Physics Solutions Chapter 3 Vectors In Physics64Gp
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Chapter 3 Vectors In Physics Q.65GP
Two students perform an experiment with a train and a ball. Michelle tides on a flatcar pulled at 8.35 m/s by a train on a straight, horizontal track; Gary stands at rest on the ground near the tracks. When Michelle throws the ball with an initial angle of 65.0° above the horizontal, from her point of view, Gary sees the ball rise straight up and back down above a fixed point on the ground, (a) Did Michelle throw the ball toward the front of the train or toward the rear of the train? Explain, (b) What was the initial speed of Michelle’s throw? (c) What was the initial speed of the ball as seen by Gary?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics65Gp

Chapter 3 Vectors In Physics Q.66GP
An off-roader explores the open desert in her Hummer. First she drives 25° west of north with a speed of 6.5 km/h for 15 minutes, then due east with a speed of 12 km/h for 7.5 minutes. She completes the final leg of her trip in 22 minutes. What are the direction and speed of travel on the final leg? (Assume her speed is constant on the leg, and that she returns to her starting point at the end of the final leg.)
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics66Gp

Chapter 3 Vectors In Physics Q.67GP
Mastering Physics Solutions Chapter 3 Vectors In Physics67Gp
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Chapter 3 Vectors In Physics Q.68GP
Mastering Physics Solutions Chapter 3 Vectors In Physics68Gp
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Chapter 3 Vectors In Physics Q.69GP
Mastering Physics Solutions Chapter 3 Vectors In Physics69
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Chapter 3 Vectors In Physics Q.70GP
Two airplanes taxi as they approach the terminal. Plane 1 taxies with a speed of 12 m/s due north. Plane 2 taxies with a speed of 7.5 m/s in a direction 20° north of west, (a) What are the direction and magnitude of the velocity of plane 1 relative to plane 2? (b) What are the direction and magnitude of the velocity of plane 2 relative to plane 1?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics70gp

Chapter 3 Vectors In Physics Q.71GP
Mastering Physics Solutions Chapter 3 Vectors In Physics71gp
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Chapter 3 Vectors In Physics Q.72GP
Initially, a particle is moving at 4.10 m/s at an angle of 33.5° above the horizontal. Two seconds later, its velocity is 6.05 m/s at an angle of 59.0° below the horizontal. What was the particle’s average acceleration during these 2.00 seconds?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics72gp

Chapter 3 Vectors In Physics Q.73GP
A passenger on a stopped bus notices that rain is falling vertically just outside the window. When the bus moves with constant velocity, the passenger observes that the falling raindrops are now making an angle of 15° with respect to the vertical. (a) What is the ratio of the speed of the raindrops to the speed of the bus? (b) Find the speed of the raindrops, given that the bus is moving with a speed of 18m/s.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics73gp

Chapter 3 Vectors In Physics Q.74GP
A Big Clock The clock that rings the bell known as Big Ben has an hour hand that is 9.0 feet long and a minute hand that is 14 feet long, where the distance is measured from the center of the clock to the tip of the hand. What is the tip-to-tip distance between these two hands when the clock reads 12 minutes after four o’clock?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics74gp

Chapter 3 Vectors In Physics Q.75GP
Mastering Physics Solutions Chapter 3 Vectors In Physics75gp
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Chapter 3 Vectors In Physics Q.76GP
Referring to Example, (a) what heading must the boat have if it is to land directly across the river from its starting point? (b) How much time is required for this trip if the river is 25.0 m wide? (c) Suppose the speed of the boat is increased, but it is still desired to land directly across from the starting point. Should the boat’s heading be more upstream, more downstream, or the saine as in part (a)? Explain.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics76gp

Chapter 3 Vectors In Physics Q.77GP
Mastering Physics Solutions Chapter 3 Vectors In Physics77gp
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Chapter 3 Vectors In Physics Q.78GP
As two boats approach the marina, the velocity of boat 1 relative to boat 2 is 2.15 m/s in a direction 47.0° east of north. If boat 1 has a velocity that is 0.775 m/s due north, what is the velocity (magnitude and direction) of boat 2?
Solution:
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Chapter 3 Vectors In Physics Q.79PP
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Chapter 3 Vectors In Physics Q.80PP
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Chapter 3 Vectors In Physics Q.81PP
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Chapter 3 Vectors In Physics Q.82IP
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Chapter 3 Vectors In Physics Q.83IP
Referring to Example Suppose the speed of the boat relative to the water is 7.0 m/s. (a) At what angle to the x axis must the boat be headed if it is to land directly across the river from its starting position? (b) If the speed of the boat relative to the water is increased, will the angle needed to go directly across the river increase, decrease, or stay the same? Explain.
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics83pp

Chapter 3 Vectors In Physics Q.84IP
Referring to Example Suppose the boat has a speed of 6.7 m/s relative to the water, and that the dock on the opposite shore of the river is at the location x = 55 m and y = 28 m relative to the starting point of the boat, (a) At what angle relative to the x axis must the boat be pointed in order to reach the other dock? (b) With the angle found in part (a), what is the speed of the boat relative to the ground?
Solution:
Mastering Physics Solutions Chapter 3 Vectors In Physics84pp