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PHY1013S GAUSS’S LAW

PHY1013S GAUSS’S LAW. Gregor Leigh gregor.leigh@uct.ac.za. GAUSS’S LAW. Calculate the electric flux through a surface. Use Gauss’s Law to calculate the electric field due to symmetric charge distributions.

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PHY1013S GAUSS’S LAW

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  1. PHY1013SGAUSS’S LAW Gregor Leighgregor.leigh@uct.ac.za

  2. GAUSS’S LAW GAUSS’S LAW • Calculate the electric flux through a surface. • Use Gauss’s Law to calculate the electric field due to symmetric charge distributions. • Use Gauss’s Law to determine the charge distribution on hollow conductors in electric fields. Learning outcomes:At the end of this chapter you should be able to…

  3. GAUSS’S LAW FLUX • is the unit vector normal to a surface. is the surface’s area vector. The amount of flow, , through the surface depends on: • the magnitude of the velocity, v; • the area of the surface, A; • the angle between and .  ( is a maximum when  = 0°; a minimum for  = 90°.) Hence:  = vAcos or just: Replacing the velocity vector with the electric field vector , we get:

  4. GAUSS’S LAW FLUX For a surface made up of small elements, each A, the total flux is For a closed (Gaussian) surface, in the limit A0, [Nm2/C] The electric flux through a Gaussian surface is proportional to the net number of electric field lines passing through that surface.

  5. GAUSS’S LAW Gaussian surface 3 1 2

  6. Gaussian surface 3 1 2 GAUSS’S LAW 1 1  < 0

  7. GAUSS’S LAW Gaussian surface 3 1 2 2 2  = 0

  8. Gaussian surface 3 1 2 GAUSS’S LAW 3 3  > 0

  9. GAUSS’S LAW  = 90°  = 180° c • A cylindrical Gaussian surface of radius R is placed in a uniform electric field, with the cylinder axis parallel to the field. b a  = 0° What is the (net) flux of the field through this surface? … …

  10. + GAUSS’S LAW When will the net flux ever NOT be zero?

  11. GAUSS’S LAW GAUSS’ LAW • The net electric flux through a Gaussian surface is proportional to the net charge enclosed: 0 = Qin   Qin Substituting for , Notes: • Qin is the net, enclosed charge. • is the totalfield through the surface. • These equations are valid only in vacuum (or air). • Gauss’s Law is both easier to use and more universal/fundamental than Coulomb’s Law.

  12. + GAUSS’S LAW GAUSS’S LAW: MULTIPLE CHARGES S3 S4 S1 S2

  13. GAUSS’S LAW USING GAUSS’S LAW TO DETERMINE ELECTRIC FIELDS • Draw the situation. • Choose a Gaussian surface appropriate to the symmetry. • Apply Gauss’s law:

  14. + GAUSS’S LAW GAUSS  COULOMB • Draw the situation… • Choose a Gaussian surface appropriate to the symmetry… • (For a point charge, choose a concentric sphere as a Gaussian surface.) • The electric field is constant over the surface and directed radially outwards, so • Apply Gauss’s law… q r

  15. – + – PHY1013S GAUSS’S LAW ZERO FIELD If there is no electric field at all, quite obviously the net flux through any Gaussian surface is also zero. (Duh!)

  16. GAUSS’S LAW CHARGE ON AN ISOLATED CONDUCTOR Any excess charge added to an isolated conductor moves entirely to the external surface of that conductor. metal cavity • The field inside the metal must be zero (otherwise there would be currents inside the conductor)… Gaussian surfaces • Therefore there is no flux through the Gaussian surfaces… •  there can be no charge within the Gaussian surfaces… •  all the charge must lie outside the Gaussian surfaces… i.e. ... All the charge lies on the external surface of the conductor.

  17. GAUSS’S LAW EXTERNAL FIELD DUE TO A CHARGED CONDUCTOR • For a non-spherical conductor, the surface charge density, , varies over the surface, and the field established around the conductor is very complex. However, for a point just outside the surface, the adjacent section of surface is small enough to be considered as flat, and the charge density as uniform…

  18. GAUSS’S LAW USING GAUSS’S LAW TO DETERMINE ELECTRIC FIELDS • Draw the situation. • Choose a Gaussian surface appropriate to the symmetry. • Apply Gauss’s law:

  19. GAUSS’S LAW EXTERNAL FIELD DUE TO A CHARGED CONDUCTOR • A cylindrical Gaussian surface with an end cap area of Ais embedded in the surface of the conductor as shown.  A The flux through the outer cap is EA. The total charge enclosed by the cylinder is given by A. Therefore, according to Gauss’s law: 0EA=A and hence:

  20. GAUSS’S LAW EXTERNAL FIELD DUE TO A CHARGED CONDUCTOR • The electric field is zero everywhere inside the conducting material. • Any excess charge is all on the surface. Summary:  • The external field lies perpendicular to the surface and is given by . • On an irregularly shaped conductor the charge collects around sharp points, but still holds true.

  21. GAUSS’S LAW USING GAUSS’S LAW TO DETERMINE ELECTRIC FIELDS • Draw the situation. • Choose a Gaussian surface appropriate to the symmetry. • Apply Gauss’s law:

  22. GAUSS’S LAW CYLINDRICAL SYMMETRY  r • For a long, thin, cylindrical insulator with a uniform linear charge density of … L we choose a cylindrical Gaussian surface with radius r and height L: The area of the curved surface is 2rL. By symmetry, the total flux through the surface is E2rL. The total charge enclosed by the cylinder is L. Therefore, according to Gauss’s law: 0E2rL = L 2r and hence: or:

  23. GAUSS’S LAW PLANAR SYMMETRY • For a large, flat, thin insulating sheet with a uniform surface charge density of …  A …we choose a cylindrical Gaussian surface with end cap area A, which pierces the sheet perpendicularly. According to Gauss’s law:0(EA + EA)=A and hence:

  24. GAUSS’S LAW PLANAR SYMMETRY • For a charged large, flat, thin conducting plate: surface charge density =1 When two oppositely charged plates are brought close together, all the charge moves to the inner faces: surface charge density =21

  25. GAUSS’S LAW SPHERICAL SYMMETRY S1 A spherical shell of radius R and charge q is surrounded by a concentric spherical Gaussian surface (S1) with radius r (where rR). r R q According to Gauss’s law:0E4r2 = q and hence, for S1: I.e. A uniform spherical shell of charge acts, on all charges outside it, as if all its charge were concentrated at its centre. [Shell theorem 1]

  26. E= 0 According to Gauss, for S2: GAUSS’S LAW SPHERICAL SYMMETRY S2 S2 is a concentric spherical Gaussian surface with radius r lying within the spherical shell of charge q (i.e. rR). r R q I.e. A uniform spherical shell of charge exerts no electrostatic force on a charged particle located inside it. [Shell theorem 2]

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