Redox Systems (CIE A Level Chemistry)

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Francesca

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Redox Systems: Ferrous & Permanganate

  • The oxidation states of transition element ions can change during redox reactions
    • A species will either be oxidised or reduced, depending on what reaction is occurring

  • To find the concentration of specific ions in solution, a titration can be performed
  • There are three particular redox titrations that need to be learnt:
    • Iron (II) (Fe2+) and permanganate (MnO4-) in acid solution given suitable data
    • Permanganate (MnO4-) and ethanedioate (C2O42-) in acid solution given suitable data
    • Copper (II) (Cu2+) and iodide (I-) given suitable data

Reaction of MnO4- & Fe2+ in acid

  • The concentration of Fe2+ ions can be determined by titrating a known volume of Fe(II) ions with a known concentration of MnO4- ions
  • During the reaction of MnO4- with Fe2+, the purple colour of the manganate(VII) ions disappears
  • The end-point is when all of the Fe2+ ions have reacted with the MnO4- ions, and the first trace of a permanent pink colour appears in the flask
    • At this point, the MnO4- is very slightly in excess

  • The two half-reactions that are involved in this redox reaction are as following:

Chemistry of Transition Elements - Ferrous & Permanganate Half-Equations, downloadable AS & A Level Chemistry revision notes

  • The half equations are combined to get the overall equation

Chemistry of Transition Elements - Ferrous & Permanganate Overall Reaction, downloadable AS & A Level Chemistry revision notes

Redox Systems: Permanganate & Oxalate

  • The second redox titration involving transition element ions that needs to be learned, is the titration of permanganate (MnO4-) and ethanedioate, sometimes known as oxalate (C2O42-) in acid solution given suitable data

Reaction of MnO4- & C2O42- in acid

  • The reaction of MnO4- with ethanedioate, C2O42- is an example of a redox reaction in which the ethanedioate ions (C2O42-) get oxidised by manganate(VII) (MnO4-) ions
  • A titration reaction can be carried out to find the concentration of the toxic ethanedioate ions
  • As before, the end point is when all of the ethanedioate ions have reacted with the MnO4- ions, and the first permanent pink colour appears in the flask
    • At this point, the MnO4- is very slightly in excess

  • The two half-reactions that are involved in this redox reaction are as following:

Chemistry of Transition Elements - Oxalate & Permanganate Half-Equations, downloadable AS & A Level Chemistry revision notes

  • The half equations are combined to get the overall equation

 

Chemistry of Transition Elements - Oxalate & Permanganate Overall Reaction, downloadable AS & A Level Chemistry revision notes

  • This is an example of an autocatalysis reaction
  • This means that the reaction is catalysed by one of the products as it forms
  • In this reaction, the Mn2+ ions formed act as the autocatalyst
  • The more Mn2+ formed, the faster the reaction gets, which then forms even more Mn2+ ions and speeds the reaction up even further
  • Transition element ions can act as autocalysts as they can change their oxidation states during a reaction

Redox Systems: Cupric & Iodide

  • The third redox titration involving transition metal ions that needs to be learnt is the titration between copper (II) ions (Cu2+) - sometimes known as cupric ions - and iodide ions (I-)

Reaction of Cu2+ & I-

  • The reaction of Cu2+ with I- is an example of a redox reaction in which the copper ions (Cu2+) oxidise the iodide ions (I-) and as a result are themselves reduced
  • The two half-reactions that are involved in this redox reaction are as follows:

 

Chemistry of Transition Elements - Cupric & Iodide Half-Equations, downloadable AS & A Level Chemistry revision notes

  • The half equations could be combined to get this overall equation

 

Chemistry of Transition Elements - Cupric & Iodide Overall Reaction, downloadable AS & A Level Chemistry revision notes

  • When excess iodide ions are reacted with Cu(II), a precipitate of copper(I) iodide and iodine is formed

2Cu2+ (aq) + 4I-(aq) →  I2(aq) + 2CuI (s)          Reaction 1

  • A titration reaction can be carried out to find an unknown concentration of the copper(II) solution
  • This is done by finding the amount of iodine which is liberated during the reaction, through a titration
  • Step 1: A known concentration of sodium thiosulfate solution is added to the mixture formed in Reaction 1 from a burette
  • Step 2: The I2 formed in Reaction 1 will react with the thiosulfate ions

I2 (aq) + 2S2O32- (aq) →  2I- (aq) + S4O62- (aq)          Reaction 2

  • Step 3: As the iodine is used, up the brownish colour of the solution gets lighter
  • Step 4: When most of the iodine colour is gone, starch is added, which turns deep blue/black with the remaining I2 (aq)
  • Step 5: Titrate further until the blue/black colour disappears, i.e. when all of the iodine has reacted
  • By knowing the number of moles of thiosulfate ions added in the titration, you can use the molar ratios from the reaction equations and work backwards to calculate the number of moles of Cu(II)
  • Step 6: Look at Reaction 2: it can be concluded that half the number of moles of I2 reacts when compared to the moles of thiosulfate that react
  • Step 7: Now look at Reaction 1: the number of moles of I2 which reacts in Reaction 2, is the moles formed in Reaction 1. The number of moles of Cu(II) is twice that of I2 (aq) (i.e. the same number of moles as thiosulfate ions added in the titration)
  • Step 8: Divide the number of moles of Cu(II) by the volume in dm3 to get the concentration of Cu(II)

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Francesca

Author: Francesca

Expertise: Head of Science

Fran studied for a BSc in Chemistry with Forensic Science, and since graduating taught A level Chemistry in the UK for over 11 years. She studied for an MBA in Senior Leadership, and has held a number of roles during her time in Education, including Head of Chemistry, Head of Science and most recently as an Assistant Headteacher. In this role, she used her passion for education to drive improvement and success for staff and students across a number of subjects in addition to Science, supporting them to achieve their full potential. Fran has co-written Science textbooks, delivered CPD for teachers, and worked as an examiner for a number of UK exam boards.