Potential Difference & Conductor Length
Potential Difference
- A cell makes one end of the circuit positive and the other negative. This sets up a potential difference across the circuit
- The potential difference across a component in a circuit is defined as;
energy transferred per unit charge
- The energy is transferred is from electrical energy into other forms, depending on the component or device being used
- Potential difference is measured in volts (V) which are equivalent to Joule per coulomb (J C−1)
- The potential difference of a power supply connected in series is always shared between all the components in the circuit
The potential difference is the voltage across each component in a circuit
- Another description of energy transfer is work done
- Therefore, potential difference can also be defined as the work done per unit charge
Potential difference is the work done per unit charge
Measuring Potential Difference
- Potential difference or voltage is measured using a voltmeter
- A voltmeter is always set up in parallel to the component being measured
Potential difference can be measured by connecting a voltmeter in parallel between two points in a circuit
Conductor Length
- The equation for resistivity is
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- Where:
- R = resistance (Ω)
- ρ = resistivity (Ω m−1)
- l = length (m)
- A = area (m−2)
- Therefore, as the length of a uniform conductor at constant temperature increases, resistance also increases
- Voltage and current are linked by Ohm's Law
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- Where
- V = potential difference (V)
- I = current (A)
- R = resistance (Ω)
- Therefore, as R increases, so must potential difference across the wire
- Potential difference increases uniformly with length
