18.2
View the full transcript and gain access to JoVE Core videos
Q1: What is electromotive force and how does it drive electron flow?
Electromotive force (emf), also called cell potential, is the driving force that causes electrons to flow between two reactants. Similar to how gravitational potential energy drives water down a waterfall, the difference in electrical potential energy between reactants drives electrons through a wire. This flow of electrons constitutes an electric current and can power electrical appliances like lightbulbs.
Q2: Why does a redox reaction in a beaker not generate electricity, but the same reaction in separated compartments does?
In a beaker, electrons transfer directly between reactants, producing no electrical current. When reactants are physically separated and connected via an external wire, electrons are forced to flow through the wire to complete the reaction. This electron flow through the external conductor constitutes an electric current, allowing the reaction to power electrical devices.
Q3: How is electric current measured and what does one ampere represent?
Electric current is measured in amperes. One ampere equals the flow of one coulomb of electrical charge per second, corresponding to 6.24 × 10^18 electrons per second. Since each electron carries a charge of 1.602 × 10^-19 coulombs, amperage quantifies the rate at which electrons move through a conductor.
Q4: What factors determine the cell potential of a redox reaction?
Cell potential depends on three key factors: the nature of the reactants involved, the temperature of the reaction, and the concentration of ions present in the solution. These variables affect the electrical potential energy difference between reactants, which directly influences the magnitude of the driving force for electron transfer and the ease with which the reaction proceeds.
Q5: How is cell potential measured and what does one volt indicate?
Cell potential is measured using a voltmeter, which reads the voltage in volts. One volt equals one joule of potential energy per coulomb of electrical charge. A high cell potential indicates a large driving force and greater ease of electron transfer between reactants, while a low cell potential suggests weaker reactivity.
Q6: Why do different metal ions show different reactivity toward copper?
Different metal ions possess different tendencies to oxidize copper, determined by their inherent redox activity. For example, silver ions spontaneously oxidize copper, while lead ions do not. This difference in redox reactivity can be quantified using cell potential, which reflects the electrical potential energy difference between the reactants and their tendency for electron transfer.
Q7: What is the relationship between cell potential and the tendency for electron transfer?
Cell potential is a direct measure of the driving force between two reactants and their tendency for electron transfer. Higher cell potentials indicate stronger driving forces and greater spontaneity of electron transfer. The cell potential reflects the difference in electrical potential energy between reactants, determining whether a redox reaction will proceed spontaneously.
Explore Related Chapters



















