Standard Electrode & Cell Potentials (Cambridge (CIE) A Level Chemistry): Revision Note
Standard Electrode & Standard Cell Potentials
Electrode potential
The electrode (reduction) potential (E) is a value which shows how easily a substance is reduced
These are demonstrated using reversible half equations
This is because there is a redox equilibrium between two related species that are in different oxidation states
For example, if you dipped a zinc metal rod into a solution which contained zinc ions, there would be zinc atoms losing electrons to form zinc ions and at the same time, zinc ions gaining electrons to become zinc atoms
This would cause a redox equilibrium
When writing half equations for this topic, the electrons will always be written on the left-hand side (demonstrating reduction)
The position of equilibrium is different for different species, which is why different species will have electrode (reduction) potentials
The more positive (or less negative) an electrode potential, the more likely it is for that species to undergo reduction
The equilibrium position lies more to the right
For example, the positive electrode potential of bromine below, suggests that it is likely to get reduced and form bromide (Br-) ions
Br2 (l) + 2e- ⇌ 2Br- (aq) voltage = +1.09 V
The more negative (or less positive) the electrode potential, the less likely it is that reduction of that species will occur
The equilibrium position lies more to the left
For example, the negative electrode potential of sodium suggests that it is unlikely that the sodium (Na+) ions will be reduced to sodium (Na) atoms
Na+ (aq) + e- ⇌ Na (s) voltage = -2.71 V
Standard electrode potential
The position of equilibrium and therefore the electrode potential depends on factors such as:
Temperature
Pressure of gases
Concentration of reagents
So, to be able to compare the electrode potentials of different species, they all have to be measured against a common reference or standard
Standard conditions also have to be used when comparing electrode potentials
These standard conditions are:
An ion concentration of 1.00 mol dm-3
A temperature of 298 K
A pressure of 1 atm
The electrode potentials are measured relative to something called a standard hydrogen electrode
The standard hydrogen electrode is given a value of 0.00 V, and all other electrode potentials are compared to this standard
This means that the electrode potentials are always referred to as a standard electrode potential (Eꝋ)
The standard electrode potential (Eꝋ) is the voltage produced when a standard half-cell is connected to a standard hydrogen cell under standard conditions
For example, the standard electrode potential of bromine suggests that relative to the hydrogen half-cell it is more likely to get reduced, as it has a more positive Eꝋ value
Br2 (l) + 2e- ⇌ 2Br- (aq) Eꝋ = +1.09 V
2H+ (aq) + 2e- ⇌ H2 (g) Eꝋ = 0.00 V
The standard electrode potential of sodium, on the other hand, suggests that relative to the hydrogen half-cell it is less likely to get reduced as it has a more negative Eꝋ value
Na+ (aq) + e- ⇌ Na (s) Eꝋ = -2.71 V
2H+ (aq) + 2e- ⇌ H2 (g) Eꝋ = 0.00 V
Standard cell potential
Once the Eꝋ of a half-cell is known, the voltage of an electrochemical cell made up of two half-cells can be calculated
These could be any half-cells and neither have to be a standard hydrogen electrode
This is also known as the standard cell potential (Ecellꝋ)
The standard cell potential can be determined by two methods:
Using the equation Ecellꝋ = Ereductionꝋ – Eoxidationꝋ
Use of this equation does require knowledge of which reaction is reduction and which is oxidation
The reduction reaction has the higher / more positive Eꝋ value
Ecellꝋ is the difference in Eꝋ between two half-cells
For example, an electrochemical cell consisting of bromine and sodium half-cells has an Ecellꝋ of:
Ecellꝋ = (+1.09) - (-2.71)
Ecellꝋ = +3.80 V
Standard Hydrogen Electrode
When a metal rod is placed in an aqueous solution, a redox equilibrium is established between the metal ions and atoms
For example, the copper atoms get oxidised and enter the solution as copper ions
Cu (s) → Cu2+ (aq) + 2e-
Oxidation of copper ions
During oxidation, copper atoms lose 2 electrons to form Cu2+ ions
The copper ions gain electrons from the metal rod and deposit as metal atoms on the rod
Cu2+ (aq) + 2e- → Cu (s)
Reduction of copper ions
During reduction, Cu2+ ions gain 2 electrons to form copper atoms
When equilibrium is established, the rate of oxidation and reduction of copper is equal
The position of the redox equilibrium is different for different metals
Copper is more easily reduced, thus the equilibrium lies further over to the right
Cu2+ (aq) + 2e- ⇌ Cu (s)
Vanadium is more easily oxidised, thus the equilibrium lies further over to the left
V2+ (aq) + 2e- ⇌ V(s)
The metal atoms and ions in solution cause an electric potential (voltage)
This potential cannot be measured directly however the potential between the metal/metal ion system and another system can be measured
This value is called the electrode potential (E) and is measured in volts
The electrode potential is the voltage measured for a half-cell compared to another half-cell
Often, the half-cell used for comparison is the standard hydrogen electrode
Standard hydrogen electrode
The standard hydrogen electrode is a half-cell used as a reference electrode and consists of:
Hydrogen gas in equilibrium with H+ ions of concentration 1.00 mol dm-3 (at 1 atm)
2H+ (aq) + 2e- ⇌ H2 (g)
An inert platinum electrode that is in contact with the hydrogen gas and H+ ions
When the standard hydrogen electrode is connected to another half-cell, the standard electrode potential of that half-cell can be read off a voltmeter
The standard hydrogen electrode (SHE)
The standard electrode potential of a half-cell can be determined by connecting it to a standard hydrogen electrode
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