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Maxwell’s Equations and Electromagnetic Waves Setting the Stage - The Displacement Current Maxwell had a crucial “leap of insight”... Will there still.

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Presentation on theme: "Maxwell’s Equations and Electromagnetic Waves Setting the Stage - The Displacement Current Maxwell had a crucial “leap of insight”... Will there still."— Presentation transcript:

1

2 Maxwell’s Equations and Electromagnetic Waves

3 Setting the Stage - The Displacement Current Maxwell had a crucial “leap of insight”... Will there still be a magnetic field around the capacitor?

4 A Beautiful Symmetry... A changing magnetic flux produces an Electric field A changing electric flux produces a Magnetic field

5 An extension of Ampere’s Law... Maxwell reasoned that Ampere’s Law would also apply to the displacement current. Clever application of Gauss’ Law here!

6 Maxwell’s Equations (first glimpse) Faraday’s Law: Ampere’s Law:

7 Maxwell’s Equations – Integral Form Faraday’s Law: Ampere’s Law: Gauss’ Law

8 Maxwell’s Equations – Differential Form Gauss’ Theorem – integral of a flux equals volume integral of divergence

9 Maxwell’s Equations – Differential Form Stoke’s Theorem: “Integral around the path equals flux of the curl”

10 Maxwell’s Equations – Differential Form

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12 The Wave Equation How fast will a wave travel along a string of density  ?

13 Two Ways to M’Es… Abstract: Physical: –Imagine a plane wave of electric field in z- direction

14 Go to Rob Salgado’s sim of this

15 Moving Fields… Moving E-Field leads to… Moving B-Field leads to…

16 It’s Alive! Well, at least it’s a wave! Combining the last two equations leads us to: example - consider the electric field part of an electromagnetic wave described by:

17 The Poynting Vector Light waves (and all electromagnetic waves) carry energy A wave has an intensity Poynting Vector

18 Radiation Pressure Light waves (and all electromagnetic waves) exert pressure

19 Accelerating Charges Radiate Power! We can show (by dimensional argument) that an accelerating charge should radiate energy at a rate given by: More detailed argumentation reveals that  = 2/3

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