E.m.f & Internal Resistance (OCR A Level Physics)

• When charge passes through a power supply such as a battery, it gains electrical energy
• The electromotive force (e.m.f) is the amount of chemical energy converted to electrical energy per coulomb of charge (C) when charge passes through a power supply

• E.m.f can be represented by the symbol ε (greek letter epsilon)
  • It is not actually a force, and is measured in volts (V)

• The e.m.f source is from a battery or a power supply

• E.m.f is equal to the potential difference across the cell when no current is flowing
• E.m.f can be measured by connecting a high-resistance voltmeter around the terminals of the cell in an open circuit, as so:

e.m.f is measured using a voltmeter connected in parallel with the cell

Internal Resistance

• All power supplies have some resistance between their terminals
  • This is called internal resistance (r)

• It is internal resistance that causes the charge circulating to dissipate some electrical energy from the power supply itself
  • This is why the cell becomes warm after a period of time

• Therefore, over time the internal resistance causes loss of voltage or energy loss in a power supply
• A cell can be thought of as a source of e.m.f with an internal resistance connected in series. This is shown in the circuit diagram below:

Circuit showing the e.m.f and internal resistance of a power supply

• Where:
  • Resistor R is the ‘load resistor’
  • r is the internal resistance
  • ε is the e.m.f
  • V_r is the lost volts
  • V_R is the p.d across the load resistor, which is the same as the terminal p.d

• The terminal potential difference (p.d) is the potential difference across the terminals of a cell
  • If there was no internal resistance, the terminal p.d would be equal to the e.m.f

• It is defined as:

V = IR

• Where:
  • V = terminal p.d (V)
  • I = current (A)
  • R = resistance (Ω)

• If a cell has internal resistance, the terminal p.d is always lower than the e.m.f
• If you have a load resistor R across the cell's terminals, then the terminal p.d V also the p.d across the load resistor

• In a closed circuit, current flows through a cell and a potential difference develops across the internal resistance
• Since resistance opposes current, this reduces the energy per unit charge (voltage) available to the rest of the external circuit
• This difference is called the ‘lost volts’
  • Lost volts is usually represented by little v
  • It is defined as the voltage lost in the cell due to internal resistance, so, from conservation of energy:
  • v = e.m.f − terminal p.d

 v = ε – V = Ir (Ohm’s law)

• Where:
  • v = lost volts (V)
  • I = current (A)
  • r = internal resistance of the battery (Ω)
  • ε = e.m.f (V)
  • V = terminal p.d (V)

• Therefore, lost volts is the difference between the e.m.f and the terminal p.d