Electric Field & Potential
- A positive test charge has electric potential energy due to its position in an electric field
- The amount of electric potential energy depends on:
- The magnitude of charge
- The value of the electric potential in the field
Work is done on a positive test charge Q to move it from the negatively charged plate A to the positively charged plate B. This means its electric potential energy increases
- Electric potential is defined as the amount of work done per unit of charge at that point
- A stronger electric field means the electric potential changes more rapidly with distance as the test charge moves through it
- Hence, the relationship between the electric field strength and the electric potential is summarised as:
The electric field strength is proportional to the gradient of the electric potential
- This means:
- If the electric potential changes very rapidly with distance, the electric field strength is large
- If the electric potential changes very gradually with distance, the electric field strength is small
- An electric field can be defined in terms of the variation of electric potential at different points in the field:
The electric field at a particular point is equal to the gradient of a potential-distance graph at that point
- The potential gradient in an electric field is defined as:
The rate of change of electric potential with respect to displacement in the direction of the field
- The graph of potential V against distance r for a negative or positive charge is:
The electric potential around a positive charge decreases with distance and increases with distance around a negative charge
- The key features of this graph are:
- The values for V are all negative for a negative charge
- The values for V are all positive for a positive charge
- As r increases, V against r follows a 1/r relation for a positive charge and -1/r relation for a negative charge
- The gradient of the graph at any particular point is the value of E at that point
- The graph has a shallow increase (or decrease) as r increases
- The electric potential changes according to the charge creating the potential as the distance r increases from the centre:
- If the charge is positive, the potential decreases with distance
- If the charge is negative, the potential increases with distance
Worked example
An electric field is set up between two pairs of oppositely charged plates, set X and set Y.
A graph showing how the electric potential V varies with distance d is shown for both set X and set Y.
State and explain which set creates the largest electric field strength.
Step 1: Recall the relationship between electric field strength and electric potential
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- The electric field strength is proportional to the gradient of the electric potential
Step 2: Interpret the gradient of the potential-distance graph
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- Set X has a larger gradient than set Y
Step 3: State and explain the conclusion
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- Set X creates a larger electric field strength
- This is because the gradient of the potential between the plates is larger than it is for set Y
Examiner Tip
Remember that whether the electric potential increases or decreases depends on the charge that is producing the potential!
