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Gauss’s law This lecture was given mostly on the board so these slides are only a guide to what was done.

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Presentation on theme: "Gauss’s law This lecture was given mostly on the board so these slides are only a guide to what was done."— Presentation transcript:

1 Gauss’s law This lecture was given mostly on the board so these slides are only a guide to what was done.

2 We have shown that the number of field lines emerging from a closed surface is proportional to the net charge enclosed or The electric flux through any closed surface is proportional to the charge enclosed Gauss’s law

3 Gauss’s law follows from the inverse square aspect of Coulomb’s law

4 TRUE or FALSE? All particles contribute to the electric field at point P on the surface. The net flux of electric field through the surface due to q 3 and q 4 is zero. The net flux of electric field through the surface due to q 1 and q 2 is proportional to (q 1 + q 2 ). All True AF Gauss’ Law

5 Gauss’s Law Gauss’ Law relates the net flux  of an electric field through a closed surface to the net charge q enc that is enclosed by that surface Gauss’ Law - in vacuum (or air) Charge outside not included Exact location of charges inside doesn’t matter, only magnitude and sign But, E is the resultant of all charges, both inside and outside Q

6 The net number of electric field lines out of each surface is the same SHAPE OF SURFACE DOESN’T MATTER

7 Flux through the surface due to ALL the charges this charge contributes ZERO FLUX as every field line from it that enters the surface at one point, leaves at another

8 Example 21.1 Field of a uniformly charged sphere Total charge Q Radius R Done on board in lecture

9 Example 21.2 Field of a hollow spherical sphere From Gauss’s law, E = 0 inside shell Read Example 21.3 Field of a point charge within a shell and TIP: SYMMETRY MATTERS!

10 Line symmetry (Next lecture) Example 21.4 Field of a line of charge (line of charge) A section of an infinitely long wire with a uniform linear charge density,. Find an expression for E at distance r from axis of wire.

11 Applying Gauss’ Law: cylindrical symmetry (line of charge) (Compare this result with that obtained using Coulomb’s law in Example 20.7, when wire is infinitely long.) Applies outside any cylindrical charge distribution

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