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Feb 25, 2011. RETARDED POTENTIALS At point r =(x,y,z), integrate over charges at positions r’ (7) (8) where [ρ]  evaluate ρ at retarded time: Similar.

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Presentation on theme: "Feb 25, 2011. RETARDED POTENTIALS At point r =(x,y,z), integrate over charges at positions r’ (7) (8) where [ρ]  evaluate ρ at retarded time: Similar."— Presentation transcript:

1 Feb 25, 2011

2 RETARDED POTENTIALS At point r =(x,y,z), integrate over charges at positions r’ (7) (8) where [ρ]  evaluate ρ at retarded time: Similar for [j]

3 So potentials at pointand time t are affected by conditions at Given a charge and current density, find retarded potentials by means of (7) and (8) Then use (1) and (2) to derive E, B Fourier transform  spectrum

4 Radiation from Moving Charges The Liénard-Wiechart Potentials Retarded potentials of single, moving charges Charge q moves along trajectory velocity at time t is charge density current density delta function

5 Can integrate over volume d 3 r to get total charge and current

6 What is the scalar potential for a moving charge? Recall where [ ] denotes evaluation at retarded time Substitute and integrate

7 Now let vector scalar then

8 Now change variables again then Velocity dot both sides  Also define unit vector

9 so This means evaluate integral at t'‘=0, or t‘=t(retard)

10 So... beaming factor or, in the bracket notation: Liénard-Wiechart scalar potential Similarly, one can show for the vector potential: Liénard-Wiechart vector potential

11 Given the potentials one can use to derive E and B. We’ll skip the math and just talk about the result. (see Jackson §14.1)

12 The Result: The E, B field at point r and time t depends on the retarded position r(ret) and retarded time t(ret) of the charge. Let Field of particle w/ constant velocityTransverse field due to acceleration

13 Qualitative Picture: transverse “radiation” field propagates at velocity c

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