Standard Cell Potentials
- Voltmeters measure the potential on the right-hand side of the cell and subtract it from the potential on the left-hand side of the cell
EMF= Eright - Eleft
- Sometimes this can be hard to remember, but it helps if you remember the phrase 'knives & forks'
Trick to remember how to calculate EMF
You hold your knife in your right hand and your fork in your left hand. EMF is right minus left
- If the standard hydrogen electrode is placed on the left-hand side of the voltmeter, then by convention Eleft will be zero and the EMF of the cell will be the electrode potential of the right-hand electrode
- For example, if the standard zinc electrode is connected to the standard hydrogen electrode and the standard hydrogen electrode is placed on the left, the voltmeter measures -0.76V
Zn2+(aq) + 2e- ⇌ Zn(s)
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- The Zn2+(aq) + 2e- ⇌ Zn(s) half-cell thus has an electrode potential of -0.76V
- If the Cu2+(aq) + 2e- ⇌ Cu(s) electrode is connected to the standard hydrogen electrode and the standard hydrogen electrode is placed on the left, the voltmeter reads +0.34V
- The Cu2+(aq) + 2e- ⇌ Cu(s) half-cell thus has an electrode potential of +0.34V
Standard electrode potential
- The standard electrode potential of a half-reaction is the emf of a cell where the left-hand electrode is the standard hydrogen electrode and the right-hand electrode is the standard electrode in question
- The equation EMF = ERHS - ELHS can be applied to electrochemical cells in two ways:
- Calculating an unknown standard electrode potential
- Calculating a cell EMF
- To be a standard electrode potential the measurements must be made at standard conditions, namely:
- 1.0 mol dm-3 ions concentrations
- 100 kPa pressure
- 298 K
Calculating an unknown standard electrode potential
- If the RHS and LHS electrode are specified, and the EMF of the cell measured accordingly, then if the Eθ of one electrode is known then the other can be deduced.
- For example, if the standard copper electrode (+0.34 V) is placed on the left, and the standard silver electrode is placed on the right, the EMF of the cell is +0.46 V.
- Calculate the standard electrode potential at the silver electrode.
EMF = ERHS - ELHS
+0.46 = EθAg - (+0.34 V)
EθAg = 0.46 + 0.34 = +0.80 V
Calculating a cell EMF
- If both SEP's are known, the EMF of the cell formed can be calculated if the right-hand electrode and left-hand electrode are specified
- For example, if in a cell the RHS = silver electrode (+0.80V) and LHS is copper electrode (+0.34 V), then
EMF = ERHS - ELHS
EMF = +0.80 - 0.34 = +0.46 V
Determining the direction of spontaneity
- To predict the spontaneous reaction, we simply need to find the relevant half equations and electrode potentials
- From this information, we can deduce the spontaneous and non-spontaneous reaction
- By using the convention:
EMF = ERHS – ELHS
- A positive EMF is obtained from the spontaneous reaction which occurs when the most negative half cell is ELHS and the most positive is ERHS
- The left side is always where oxidation takes place so we can also us an alternative form of the relationship:
EMF = Ereduction – Eoxidation
Worked example
Using data from Section 19 of the Data Book, determine if the reaction shown is spontaneous at standard conditions
Sn (s) + Mn2+ (aq) → Sn2+ (aq) + Mn (s)
Section 19 of the Data Book shows the following half-reactions:
Sn2+ (aq) + 2e- → Sn (s) Eθ = -0.14 V
Mn2+ (aq) + 2e- → Mn (s) Eθ = -1.18 V
Answer:
- Manganese is the more negative value, so will be ELHS or Eoxidation in the spontaneous reaction
- EMF =ERHS – ELHS = (-0.14) - (-1.18) = +1.04
- For oxidation to take place, the manganese must lose electrons and the tin(II) must gain electrons
- Mn (s) → Mn2+ (aq) + 2e- and Sn2+ (aq) + 2e- → Sn (s)
- So, the spontaneous reaction is
- Mn (s) + Sn2+ (aq) → Mn2+ (aq) + Sn (s)
- Therefore, the reaction in the question is not spontaneous
- The Eꝋ values of a species indicate how easily they can get oxidised or reduced
- In other words, they indicate the relative reactivity of elements, compounds and ions as oxidising agents or reducing agents
- The electrochemical series is a list of various redox equilibria in order of decreasing Eꝋ values
- More positive (less negative) Eꝋ values indicate that:
- The species is easily reduced
- The species is a better oxidising agent
- Less positive (more negative) Eꝋ values indicate that:
- The species is easily oxidised
- The species is a better reducing agent
Diagram to show the trends in oxidising and reducing power
Metals with the most negative Eθ values are the strongest reducing agents and non-metals with the more positive Eθ values are the strongest oxidising agents
Examiner Tip
A word of caution
- Although the positive Eθ indicates a reaction should take place, you might not actually see anything taking place if you constructed a cell that is predicted to be spontaneous
- This is because like free energy changes, Eθ only predicts the energetic feasibility of a reaction and it does not take into account the rate of a reaction
- A reaction could have a really high activation energy making it impossibly slow at room temperature
'THERMODYNAMICS PREDICTS; KINETICS CONTROLS'
