1. Zn  Zn2+ + 2e- (oxidation) Cu 2+ + 2e-  Cu (reduction)
Electrode Potentials
In a redox reaction, electrons are transferred between the reacting chemicals.
Zinc reacts with aqueous copper (II) ions in a redox reaction:
Zn (s) + Cu2+ (aq)  Zn2+ + Cu (s)
This can be split into two half equations for oxidation and reduction:
Zn  Zn2+ + 2e- (oxidation)
Cu e-  Cu (reduction)
This is an electrochemical cell. It contains two half cells, within each of which oxidation and reduction take place separately. The circuit is completed using a wire which transfers electrons between the half cells and a salt bridge which transfers ions between the half cells.
A high resistance voltmeter is used to measure the potential difference between the two half cells. The high resistance of the voltmeter ensures that current flow is minimised so that the potential difference is at its maximum (known as the electromotive force).
At the positive electrode, electrons are accepted and flow into the electrode. Therefore, reduction occurs at the positive electrode; the copper accepts the two electrons from the zinc.
At the negative electrode, electrons are released and flow through the wire. Therefore, oxidation occurs at the negative electrode; the zinc pushes its two electrons into the wire.

2. Types of Half Cell Metal in contact with a solution of its ions
Metal electrode in contact with a solution containing ions of the same metal. Examples include copper, tin and zinc;
Cu e-  Cu; Sn e-  Sn; Zn e-  Zn
2. Gas in contact with a solution of its ions
Platinum inert electrode in contact with a solution of the ions of the gas present. Examples include the standard hydrogen electrode and chlorine:
2H+ + 2e-  H2; Cl2 + 2e-  2Cl-
3. Ions of different oxidation states in solution
An inert platinum electrode is used to allow electrons to pass into the half cell. The concentrations of the different ions must be the same, 1.0 moldm-3 . Examples of this include iron (III) and iron (II), copper (II) and copper (I); non metal examples include iodine and iodide, bromine and bromide, and manganate (VII) and manganese (II).

3. Standard Electrode Potentials
A hydrogen half cell is used as the standard measurement of electrode potentials.
The conditions must be controlled:
Temperature: 298 K
Solution concentration: 1.0 moldm-3
Pressure of gas: 100kPa
2H+ + 2e-  H2
The hydrogen half cell comprises:
1.0 moldm-3 hydrochloric acid as the source of H+ ions
Supply of Hydrogen gas
Inert platinum electrode on which the half reaction takes place.
The standard electrode potential of a half cell, Eθ, is the e.m.f. Measured when the half cell is connected to a standard hydrogen half cell under standard conditions of 298K, 1moldm-3 solutions and 100kPa gas pressure.
The standard electrode potential of a half cell represents its contribution to the cell e.m.f. The contribution made by the hydrogen half cell to the cell e.m.f. is defined as 0 V. The sign of the standard electrode potential of a half cell indicates its polarity compared to the hydrogen half cell.

4. Calculating Standard Cell Potentials
The standard cell potential is calculated by:
Eθcell = Eθpositive – (Eθnegative)
Eθcell = (-0.76)
= 1.56 V
Determining the redox equation for the cell reaction
Ag+ + e-  Ag Eθ = 0.80 V
Fe2+ + 2e-  Fe Eθ = V
Decide which is the most positive half equation. This remains unchanged – it is reduction.
The most negative half equation is reversed so that it is clear to see that this is the one which provides the electrons, and proceeds to the left – this is oxidation.
Balance for electrons and add the two half equations.
Silver is most positive – therefore it stays the same as this is reduction. The iron equation gets reversed – it donates the electrons and is therefore oxidation. We then balance by multiplying the silver equation by 2 to get;
2Ag+ + Fe  2 Ag + Fe2+

5. The Electrochemical Series
Note: Equations in the electrochemical series are always given as reduction equations, with the electrons on the left hand side.
The more negative the Eθ value, the further the equilibrium lies to the left: the more readily the species loses electrons, and therefore the easier it itself is oxidised.
Strongest Reducing Agent
Example:
Mg2+ 2e-  Mg (E θ =-2.37)
Cu2+ 2e-  Cu (E θ =0.34)
The position of the magnesium equilibrium will lie further to the left because the value is more negative. The Mg more readily loses electrons, and is therefore the stronger reducing agent.
Increasing tendency to accept electrons, decreasing tendency to release electrons.
The more positive the Eθ value, the further the equilibrium lies to the right: the more readily the species gains electrons, and therefore the easier it itself is reduced.
Strongest Oxidising Agent
The more positive the Eθ value, the more likely the reaction is to occur with a flow of electrons from left to right.

6. Explaining Reaction Feasibility
An oxidising agent can oxidise a reducing agent with a more negative E θ value.
Cr2O H+ + 6e Cr3+ + 7H2O
Ag e Ag
Oxidising Agents
Reducing Agents
E θ = +1.33v
E θ = +0.80v
Example: Can acidified dichromate oxidise Ag?
Answer: Acidified Cr2O72- can oxidise Ag because:
Acidified chromium is a more powerful oxidising agent that Ag+
E θ for the reduction of acidified chromium is more positive than the E θ for the reduction of Ag+
The half cell reaction proceeds in the direction
Cr2O H+ + 6e-  2Cr3+ + 7H2O
MnO H+ + 5e Mn2+ + 4H2O
Cr2O H+ + 6e Cr3+ + 7H2O
Oxidising Agents
Reducing Agents
E θ = E θ = +1.33v
A reducing agent can reduce an oxidising agent with a more positive E θ value.
Example: Can Cr3+ reduce acidified MnO4-?
Answer: Cr3+ can reduce acidified manganate because:
Cr3+ is a more powerful reducing agent than Mn2+
E θ for the reduction of acidified chromium is more negative than the E θ for the reduction of MnO4-
The half cell reaction proceeds in the direction
2Cr3+ + 7H2O  Cr2O H+ + 6e-

7. Effect of Concentration on Cell Voltage
For changes at the negative electrode:
For changes at the positive electrode:
Zn Zn2+ + 2e-
If we move this equilibrium to the right, by reducing the concentration of Cu or increasing the concentration of Cu2+ , the positive electrode will become more positive, because Cu is more able to accept electrons.
If the positive electrode becomes more positive, the cell voltage increases.
If we move this equilibrium to the right, by increasing the concentration of Zn or decreasing the concentration of Zn2+ , the negative electrode will become more negative, because Zn is more able to donate electrons.
If the negative electrode becomes more negative, the cell voltage increases.
Cu2+ + 2e Cu
If we move this equilibrium to the left, by increasing the concentration of Zn2+ or decreasing the concentration of Zn , the negative electrode will become more positive – because less electrons are produced.
If the negative electrode becomes less negative, the cell voltage decreases.
If we move this equilibrium to the left, by increasing the concentration of Cu or decreasing the concentration of Cu2+ , the positive electrode will become less positive – because Cu2+ is more able to donate electrons.
If the positive electrode becomes less positive, the cell voltage decreases.

8. Fuel Cells Acid Membrane Hydrogen Fuel Cell
Alkali Membrane Hydrogen Fuel Cell
Negative electrode: 2H+ + 2e H2
Positive Electrode: ½ O2 + 2H+ + 2e H2O
Overall: H2 + ½ O2 H2O
Positive: ½ O2 + H2O + 2e OH-
Negative: 2H2O + 2e H2 + 2OH-
Overall: H2 + ½ O2 H2O
At the negative electrode, hydrogen gas is oxidised to form H+ ions and electrons. The electrons flow in the external circuit. The hydrogen ions diffuse through a permeable membrane to the positive electrode where they react with oxygen forming water – the oxygen is reduced.
At the negative electrode, hydrogen is oxidised. At the positive electrode, oxygen is reduced. The OH- ions produced from the reduction of oxygen diffuse across a partially permeable membrane and react with the Hydrogen to form water at the negative electrode.

9. Fuel Cells
Hydrogen gas is difficult to store. Possible methods of storage include:
as a liquid under pressure or low temperature
Adsorbed on the surface of a solid material
Absorbed within a solid material
Absorption – H2 molecules dissociate into H atoms which are incorporated as hydrides within a solid lattice.
Fuels used in modern cars include hydrogen and other hydrogen rich fuels such as methanol or ethanol which are converted into hydrogen gas by an on board reformer.
Advantages of Fuel Cell Vehicles
Less pollution as water is the only product
No carbon dioxide is produced
Greater efficiency as fuel cell vehicles can be up to 60% efficient compared to 22% for a diesel vehicle.
Adsorption – H2 molecules attach to the surface of a material
Disadvantages of Fuel Cell Vehicles
Storing and transporting hydrogen is difficult
The adsorber or absorber in fuel cells have limited lifetimes and high production costs
Toxic chemicals are used in the production of fuel cells.
The Hydrogen Economy is the use of hydrogen as a major fuel. It may be a fuel for the future, but there are a number of factors to consider: hydrogen is difficult to handle and store; hydrogen has not gained general acceptance as a fuel from the public; the initial manufacture of hydrogen (by electrolysis form water or other sources) requires energy; there is currently no infrastructure designed to supply hydrogen as a fuel.