The reduction potential of a cell is directly related to the Gibbs free energy by the equation below.

As the reduction potential of a cell becomes more and more positive, the Gibbs free energy value becomes more and more negative.

Keep in mind that a galvanic cell will always have a positive voltage, so you can disregard the negative options. The half reactions show the voltage that will result if the element in question is reduced; however, an oxidation-reduction reaction will always have one element oxidized and another element reduced. In the equation shown, solid zinc (Zn) is oxidized, so the voltage of its half reaction is inverted to +0.76V. Next, you add the voltage of iron's reduction, resulting in the overall voltage of the galvanic cell.

An electrolytic cell is best thought of as a cell that requires an external power source in order to work. The reaction will go in the opposite direction of a galvanic cell, meaning that the cell potential will also be inversed and the reaction will be non-spontaneous. As a result, cell potential would be negative in an electrolytic cell.

Since the reaction is taking place under standard conditions, we can determine the free energy of the reaction by using the equation.

n is the number of moles of electrons transferred in the balanced reaction, F is Faraday's constant, and E^o is the cell potential for the reaction.

In the given reaction calcium, , is oxidized (loses electrons) and gold, , is reduced (gains electrons).

We are only given the reduction potentials. The oxidation potential of  is the negative of the reduction potential: .

Recall that only the moles of electrons must balance for these reactions, therefore no multiplication of the standard potentials is needed when balancing mole atoms; thus the cell potential is the sum of the calcium oxidation potential and the gold reduction potential.

The reduction potential of  is , so the corresponding oxidation potential of  is .

For a substance to oxidize  to , it must have reduction potential greater than , so that the sum of the reduction potential of this compounds and the oxidation potential of  is positive.

The only choice that meets this requirement is .

As drawn above, the reaction must involve the oxidation of copper (lower reduction potential) and the reduction of silver (higher reduction potential). Reduction always means that a species gains electrons.

The correct answer is , as we would need to balance the loss of positive silver ions in that half cell. Silver has the greater reduction potential, and is therefore gaining electrons to become more negative. As the negative charge develops, it will attract the positive potassium ions in the salt bridge.

This is an example of a concentration cell. If you have two half cells, each made of the same chemical species, and connect them with a wire, the cell will generate a voltage as it attempts to correct the disequilibrium induced by the concentration difference.

The function of a voltaic cell requires the generation and dissolution of ions. Acetic acid is the only answer choice with a net dipole moment, and would therefore be the only one to dissolve the ions produced. The other choices would be unable to dissolve the ions, and the cell would not function.