1. Electric Fields Year 13

2. Electrostatic force Like charges repel, unlike charges attract How does this force act if charges are not in contact? –An electric field exists

3. Electric field lines An electric field is a region where a charged body experiences an electrostatic force Like gravitational fields, we can represent electric fields by field lines –Lines show the direction of the force experienced by a positive test charge –Lines never cross –The more lines, the stronger the field –Lines start and stop at charges (or ∞) Experiment to see field patterns

4. Electric field patterns

5. Equipotentials Equipotentials join points in a field at the same potential –No work is done moving along equipotentials Equipotentials are perpendicular to field lines Any conductor is an equipotential surface –Because charge is free to spread out

6. (resourcefulphysics.org) TAP 406.3

7. Coulomb’s Law  0 is called the permittivity of free space. Permittivity is a property of a material that is indicative of how well it supports an electric field. Different materials have different permittivities, and so the value of k in Coulomb’s law will change for different materials.

8. Coulomb’s Law Inverse square law, like gravity Attractive (-) or repulsive (+) force Valid for point charges or charged spheres

9. Worked example –k = 1/ (4  0 ) = 9.0  10 9 N m 2 C -2 –mass of an electron = 9.11  10 -31 kg –mass of a proton = 1.67  10 -27 kg –G = 6.67  10 -11 N m 2 kg -2 What is the force of repulsion between two electrons held one metre apart in a vacuum? What is the gravitational force of attraction between them? By what factor is the electric repulsion greater than the gravitational attraction? TAP 407.1

10. Electric field strength A property of the field, not the test charge Field strength is the Force felt by a unit charge

11. Potential energy Zero electric potential energy defined at infinity Have to do work to bring a charge +q a distance r from a charge +Q Work is stored as electrical potential energy If two charges are opposite, it takes work to separate them, potential energy is negative. –Must keep track of signs! +Q+Q P r +q+q Infinity (∞)

12. Electrical potential Potential is the potential energy per unit charge –Units: J/C, or volts –A property of the field, not the charge experiencing the field Field strength=-potential gradient

13. Potential around a positive charge Potential and electric field intensity E = - dV/dr Potential (V) Distance (x) 28164 4 2 8 High field intensity Low field intensity (resourcefulphysics.org)

14. Charged conducting sphere All charge resides on the outside of the sphere Electric field inside=0 Potential inside is constant

15. We can now also understand why it is that a conductor is an equipotential surface. Inside a conductor, no electric field can exist – if it did, the charges would feel a force and move around in such a way as to reduce the field. At some point equilibrium is reached and the field is zero. If the field is zero, then the potential gradient must be zero – i.e. the conductor is an equipotential surface.

16. Uniform electric field Found between two parallel plates –Equally spaced field lines –Equally spaced equipotentials F=EQ=ma –So a charge will experience uniform acceleration from one plate towards the other d

17. Electron beam cathode +5 kV anode 0 V Accelerating charges Electrons experience a force Work done=QV (charge x pd between two points)=energy gained moving with field Found in electron guns (CRTs)

19. V x =3, a x =0, V y (t=0)=0, a y =2. Motion of a body under constant upward acceleration

20. Cathode Ray Tube (CRT)

22. Robert Millikan

23. Millikan’s oil drop experiment

24. Millikan’s Apparatus

25. Comparing electric and gravitational fields

27. Electric and gravitational fields Similarities –For point charges or masses, the variation of force with distance follows the inverse square law. –Both exert a force from a distance, with no contact. –The field strength of both is defined in terms of force per unit of the property of the object that causes the force (i.e. mass and charge). Differences –Gravitational fields can only produce forces of attraction, whereas electric fields can produce attraction and repulsion. –Objects can be shielded from an electric field, they cannot however be shielded from a gravitational field –Electrostatic force is many orders of magnitude greater than gravitational force.