TOPIC 4 Electrostatic Potential

1. TOPIC 4Electrostatic Potential

2. Potential Energy • Consider the familiar case of gravitational potential energy. • Gravitational force acts downwards • To move an object upwards, an applied external force is required, opposite to the gravitational force • Gravitational potential energy increases as an object is moved upwards • The zero of gravitational potential energy is arbitrary.

3. Electrostatic Potential Energy • Now consider a charge in an electric field • Electrostatic force = qE acts to right. • An external force Fext = –qE, does work Wext = Fextx = –qEx in moving q x to the left. • Note in this case x is negative, so Wext is positive! • The change (increase) in potential energy of q is thus U = –qEx .

4. Electrostatic Potential • The potential energy obviously depends on the size of q. • Electrostatic potential V is defined as the potential energy of a unit charge. • So • Note: • Unit of potential is Volt = 1 Joule per Coulomb • Zero of potential is arbitrary – e.g. value at infinity

5. In general, since work done is The potential difference between two points is Example 1 Find the potential about a point charge Q. Example 2 Find the potential about a conducting sphere of radius R carrying charge Q.

6. Example 3 Find the electrostatic potential both outside and inside the insulating sphere carrying a uniform charge density, as discussed in the previous topic.

7. Electric Field from Potential We have seen that In the case of a radial field, This can be inverted, to give Example: Use the expression for potential to find the field about a point charge

8. In general we can write as So Or where Alternative units for E: It is more common to use Volts per metre (V m–1) instead of N C–1.

9. Potential Energy of a System of Charges Consider two charges, Q and q, separated by r. The potential due to Q at q is The potential energy is We can also consider the system as a potential due to q at Q: So the potential of Q is BUT U is the total energy of the system of the two charges!! Do not add two contributions.

10. Potential Energy of Continuous Charge Distribution How much potential energy is stored in a distribution of charge, e.g. a charged conducting sphere? Consider adding a small charge dq to a sphere already carrying Q. The increase in potential energy is To build up the a charge Qtot from zero, the increase is Note integrating gives a factor ½!! Why doesn’t U = QV(R)??

11. Motion of free charges A free charge in an electric field will move due to the electrostatic force. Total energy is conserved – it will lose potential energy U and gain kinetic K. K + U = 0 Since U = q V, K = –q V. Electron-volt – unit of energy 1 eV = change in kinetic energy when an electron (of charge e) moves through potential difference of 1 V. 1 eV = 1.610–19 J

12. Example 4 A proton is released from rest in a uniform electric field of magnitude 8.0104 V m–1. The proton travels a distance of 0.5 m in the direction of E. (a) Find the change in electric potential between start and end points. (b) Find the change in potential energy of the proton-field system as a result of this displacement. (c) Find the speed of the proton at the end point.

13. Example 5 Four equal charges, of size Q, are positioned at the corners of a square of side a. What is their potential energy due to electrostatic interactions?(Take U = 0 when the charges are infinitely spaced.)