P1. Which equation can be used to get the continuity equation from Maxwell’s eqns? a) 3 b) 4 c) 5 d) 6 e)7.

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Presentation transcript:

P1. Which equation can be used to get the continuity equation from Maxwell’s eqns? a) 3 b) 4 c) 5 d) 6 e)7

Maxwell’s equations in vacuum To derive a wave equation, we have to differentiate equations and then substitute into each other. P2. What is the starting Maxwell’s Eqn (1-4) to get:

Wave equation in free space (vacuum) “To Maxwell, mystery was revealed— how light could move through space. A change in E makes changing B, but B makes E, and off they race!”

a 3-D wave equation for each component!

Nature of wave equation What does this mean mathematically? P2. Sketch f(t) at points x1 and x2. Get the signs of first and second derivative right a)did it b)tried f(x, t) = F(x - c t) + G(x + c t)

Wave equation P3. is a solution to It is also a solution to ____: 1) 2) a)eqn 1 b)eqn 2 c)both d)neither

With light in a material, we add “source terms” on right.

Electrons bound in atoms form dipoles in a “dielectric” (insulator) Dipole from two equal charges +q, -q. Dipole of a polarized atom

Electrons bound in atoms form dipoles in a “dielectric” (insulator) Need to define a useful volume for calculating how atoms influence light fields: it must be large compared to ___________, and small compared to ______________ So in our theory will be continuous, smooth functions in space…no atomic-scale features All these atoms get replaced by

Polarization P of a material with many atoms or molecules: P will oscillate when light goes through a material! So Oscillating P is a current, and a direct source of B

Can P provide a charge density, and be a direct source of E? Yes, if If the polarization grows to the right, it acts like a steadily increasing net charge density

Which is hardest to model (most likely to have) charge For light ( >>d_atom), amorphous materials are more uniform than crystals, because of directional differences in crystals Glass

So in the most common optical materials (glass, plastics, water, air…all amorphous):

What does mean? b.E field at a point spreads out due to charge nearby c. E fields near a point spread out due to charge there d. The E field’s change at a point is due to charge there e. The E field’s change at a point is due to charge nearby Review

What does “displacement current” at some point represent? a.charges building up at that point b.charges passing that point c. electric field changing at that point d. magnetic field changing at that point Review