Change of Iron(III) Ion to Iron(II) Ion

Redox reaction in the displacement of metals from its salt solution

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Redox reaction in the displacement of metals from its salt solution

  • Generally, metals are good electron donors and therefore are good reducing agents. However, different metals have different strength as reducing agents.
  • The strength of metals as reducing agents can be compared by using the electrochemical series.
  • The electrochemical series lists metals according to their electropositivity, that is, according to their ability to lose electrons to form positive ions.
    Redox reaction in the displacement of metals from its salt solution 1
  • The higher the position of a metal in the electrochemical series, the more electropositive the metal is, the easier it is for the metal to lose its electrons. Thus, the better reducing agent the metal is.
  • On the other hand, the ability of a metal ion to accept electrons increases down the series. Thus, the strength of a metal ion as an oxidising agent increases down the electrochemical series.
  • In a displacement of metal, a more electropositive metal will displace a less electropositive metal from its salt solution.
    (a) The more electropositive metal acts as the reducing agent. It loses electrons and undergoes oxidation to form positive ions.
    (b) The ions of the less electropositive metal act as an oxidising agent by accepting the electrons. While doing so, the ions are reduced to metallic atoms.
    (c) In short, there is an electron transfer from the more electropositive metal to the ions of the less electropositive metal.

 

Oxidation and reduction in the displacement of metals experiment

Aim: To investigate oxidation and reduction in the displacement of metals.
Materials: Zinc strip, copper strip, 0.5 mol dm-3 copper(II) sulphate solution, 0.1 mol dm-3 silver nitrate solution, sandpaper.
Apparatus: Test tubes, test tube rack.
Procedure:

  1. 2 cm3 of 0.5 mol dm-3 copper(II) sulphate solution and 2 cm3 of 0.1 mol dm-3 silver nitrate solution are poured into two separate test tubes.
  2. A strip of zinc and a strip of copper are cleaned with sandpaper. The strips are then dropped into the test tubes as shown in Figure.
    Redox reaction in the displacement of metals from its salt solution 2
  3. Any change in colour and whether any metal is deposited are observed.

Observations:

Test tubeObservations
X
  • The blue colour of the solution slowly fades until it becomes colourless.
  • The zinc strip dissolves.
  • A brown solid is deposited.
Y
  • The colourless solution slowly turns blue.
  • The copper strip dissolves.
  • A silvery grey solid is deposited.

Discussion:

  1. In test tube X, zinc displaces copper from its salt solution.
    (a) Zinc is more electropositive than copper. Thus, zinc acts as the reducing agent, losing electrons to form zinc ions. By doing so, zinc is oxidised. This explains why the zinc strip dissolves.
    Redox reaction in the displacement of metals from its salt solution 3
    (b) The electrons are accepted by copper(II) ions in the solution. Thus, copper(II) ions act as the oxidising agent and are reduced to metallic copper. The brown solid deposited in test tube X is copper metal.
    Redox reaction in the displacement of metals from its salt solution 4
    (c) The decreasing amount of copper(II) ions in the solution causes the solution to slowly change colour from blue to colourless.
    (d) The redox reaction that occurs can be represented by the following equation.
    Redox reaction in the displacement of metals from its salt solution 5
  2. In test tube Y, copper displaces silver from its salt solution.
    (a) Copper is more electropositive than silver. So, copper acts as the reducing agent, losing electrons to form copper(II) ions. In other words, copper is oxidised. This explains why the copper strip dissolves.
    Redox reaction in the displacement of metals from its salt solution 6
    (b) The increasing amount of copper(II) ions in the solution causes the solution to slowly change colour from colourless to blue.
    Redox reaction in the displacement of metals from its salt solution 7
    (c) The electrons are accepted by silver ions in the solution. Thus, silver ions act as the oxidising agent and are reduced to silvery grey silver.
    (d) The redox reaction that occurs can be represented by the following equation.
    Redox reaction in the displacement of metals from its salt solution 8

Conclusion:
A more electropositive metal can displace a less electropositive metal from its salt solution whereby the more electropositive metal acts as the reducing agent and the ions of the less electropositive metal act as the oxidising agent.

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Changing of iron(II) ions to iron(III) ions and vice versa

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Changing of iron(II) ions to iron(III) ions and vice versa

  1. Iron exhibits two oxidation numbers
    (a) +2 as iron(II) ion, Fe2+
    (b) +3 as iron(III) ion, Fe3+
  2. An aqueous solution containing iron(II) ions, Fe2+ is pale green in colour, whereas that containing iron(III) ions, Fe3+ is yellow/yellowish-brown/ brown in colour.
  3. Changing iron(II) ions to iron(III) ions is an oxidation and therefore requires an oxidising agent.
    Changing of iron(II) ions to iron(III) ions and vice versa 1
  4. On the other hand, changing iron(III) ions to iron(II) ions is a reduction and therefore requires a reducing agent.
    Changing of iron(II) ions to iron(III) ions and vice versa 2

 

Table: Detecting the presence of iron(II) ions and iron(III) ions

ReagentWith iron ionsObservation
Sodium hydroxide solution or ammonia solutionFe2+Green precipitate, insoluble in excess alkali
Fe3+Brown precipitate, insoluble in excess alkali
Potassium hexacyanoferrate(ll) solutionFe2+Light blue precipitation
Fe3+Dark blue precipitation
Potassium hexacyanoferrate(lll) solutionFe2+Dark blue precipitation
Fe3+Greenish-brown solution
Potassium/ammonium thiocyanate solutionFe2+Pale red colouration
Fe3+Blood-red colouration

The following are other oxidising agents that can replace bromine water in changing iron(II) ions to iron(III) ions.
Changing of iron(II) ions to iron(III) ions and vice versa 3

Other reducing agents that can replace zinc powder in changing iron(III) ions to iron(II) ions are as follows.
Changing of iron(II) ions to iron(III) ions and vice versa 4

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Changing of iron(II) ions to iron(III) ions and vice versa experiment

Aim: To investigate oxidation and reduction in the change of iron(II) ions to iron(III) ions and vice versa.
Materials: 0.5 mol dm-3 freshly prepared iron(II) sulphate solution, 0.5 mol dm-3 iron(III) sulphate solution, bromine water, zinc powder, 2.0 mol dm-3 sodium hydroxide solution, filter paper.
Apparatus: Dropper, spatula, test tubes, test tube holder, Bunsen burner, filter funnel, test tube rack.
Procedure:
A. Changing of iron(II) ions to iron(III) ions

  1. 2 cm3 of 0.5 mol dm-3 iron(II) sulphate solution is poured into a test tube.
  2. Using a dropper, bromine water is added to the solution drop by drop.
  3. The test tube is warmed gently.
  4. 2.0 mol dm-3 sodium hydroxide solution is added slowly to the mixture until in excess.

B. Changing of iron(III) ions to iron(II) ions

  1. 2 cm3 of 0.5 mol dm-3 iron(III) sulphate solution is poured into a test tube.
  2. Half a spatula of zinc powder is added to the solution.
  3. The mixture is filtered.
  4. 2.0 mol dm-3 sodium hydroxide solution is added slowly to the filtrate until in excess.

Observations:

ActivityReagentObservations
ABromine waterBromine water decolourises. The solution changes colour from pale green to yellow.
Sodium hydroxide solutionBrown precipitate is formed. It is insoluble in excess alkali.
BZinc powderSome of the zinc powder dissolves. The solution changes colour from brown to pale green.
Sodium hydroxide solutionGreen precipitate is formed. It is insoluble in excess alkali.

Discussion:
A. Changing of iron(II) ions to iron(III) ions

  1. Bromine water oxidises iron(II) ions, Fe2+ to iron(III) ions, Fe3+. The presence of Fe3+ ions is confirmed by the formation of brown precipitate with sodium hydroxide solution.
  2. Fe2+ ions lose their electrons and are oxidised to Fe3+ ions.
  3. Bromine molecules, which give the bromine water its brown colour, gain the electrons and are reduced to colourless bromide ions, Br. This explains why the bromine water is decolourised.
  4. In this reaction, bromine water acts as the oxidising agent, where as Fe2+ ions act as the reducing agent.
    Changing of iron(II) ions to iron(III) ions and vice versa 5

B. Changing of iron(III) ions to iron(II) ions

  1. Zinc powder reduces iron(III) ions, Fe3+ to iron(II) ions, Fe2+. The presence of Fe2+ ions is confirmed by the formation of green precipitate with sodium hydroxide solution.
  2. Zinc atoms lose their electrons and are oxidised to zinc ions, Zn2+. This explains why zinc powder dissolves in iron(III) sulphate solution.
  3. Fe3+ ions accept these electrons and are reduced to Fe2+ ions.
  4. In this reaction, Fe3+ ions act as the oxidising agent, whereas zinc acts as the reducing agent.
    Changing of iron(II) ions to iron(III) ions and vice versa 6

Conclusion:

  1. Bromine water acts as an oxidising agent, changing iron(II) ions to iron(III) ions.
  2. Zinc acts as a reducing agent, changing iron(III) ions to iron(II) ions.