⚡ Electromotive force (e.m.f.) is the energy supplied per unit charge by a source such as a battery or generator. It is the maximum potential difference that can drive current through a circuit when no current is flowing. The symbol is often ε.
The unit of e.m.f. is the volt (V). One volt is defined as the potential difference that will move one coulomb of charge through a circuit while doing one joule of work:
\$V = \frac{W}{Q}\$
where \$W\$ is work in joules and \$Q\$ is charge in coulombs. Thus,
\$1\;\text{V} = 1\;\frac{\text{J}}{\text{C}}.\$
Think of a battery like a water pump. The e.m.f. is the pressure the pump creates, pushing water (electric charge) through a pipe (circuit). The higher the pressure (e.m.f.), the more water can flow. Just as a pump can push water uphill, a battery can push charge against a potential difference.
When current flows, the potential difference \$V\$ across a component is the energy lost per unit charge:
\$V = \frac{\Delta W}{Q}.\$
Unlike e.m.f., this voltage is measured across the component while current is flowing and can be less than the e.m.f. of the source due to internal resistance.
A 1.5 V battery supplies a current of 0.5 A to a resistor. Calculate:
Solution:
| Quantity | Symbol | Unit |
|---|---|---|
| Electromotive Force | ε | V (volts) |
| Potential Difference | V | V (volts) |
| Charge | Q | C (coulombs) |
| Work | W | J (joules) |