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Physics 777 Plasma Physics and Magnetohydrodynamics (MHD) Instructor: Gregory Fleishman Lecture 4. Linear Waves in the Plasma 30 September 2008.

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Presentation on theme: "Physics 777 Plasma Physics and Magnetohydrodynamics (MHD) Instructor: Gregory Fleishman Lecture 4. Linear Waves in the Plasma 30 September 2008."— Presentation transcript:

1 Physics 777 Plasma Physics and Magnetohydrodynamics (MHD) Instructor: Gregory Fleishman Lecture 4. Linear Waves in the Plasma 30 September 2008

2 Plan of the Lecture MHD Waves Waves in Isotropic Plasma Waves in Magnetized Plasma Emission of Waves by a Given Electric Current Emission by Rectilinearly Moving Charge, General Derivation

3 Section 1. MHD Waves (see Somov, Chapt. 15)

4 Fourier transform yields:

5 Section 2. Waves in Isotropic Plasma Transverse (free-space) modes

6 Longitudinal Waves Maxwellian Plasma where 1) Use iterations to solve

7 Ion Sound Waves

8 For if

9 Section 3. Waves in Magnetized Plasma

10 Zeros and Resonances Resonances Show that this means quasilongitudinal wave E||k if

11 Substitution of tensor components into coefficient A yields: This Eq. has three roots Neglecting ion contribution, we obtain two of three:

12 Asymptotic expressions

13 Zeros Neglecting ion contribution, we find: F w Z X

14 X Z O F-w A Normal waves for oblique propagation Simplifications: 1 2 Whistler mode

15 Waves in Hot Plasma Recall: It is convenient to express this via Bessel functions

16 Maxwellian plasma

17 Bernstein Modes

18 Section 2. Macroscopic Maxwell Equations. Linear response Introduce polarization vector; continuity Eqn. is fulfilled: Form displacement vector: D=E+4  P; the most general (non- local) linear relation for statistically uniform medium reads:

19 Section 4. Emission of Waves by a Given Electric Current Recall: where is the Maxwellian tensor, j is an external electric current (including nonlinear plasma current in a general case). Let’s solve this inhomogeneous algebraic equation for E - energy loss of a given current (from electrodynamics)

20 where In the basis of the eigen-vectorswe obtain diagonal form Substitution yields:

21

22 where

23 Section 5. Emission by Rectilinearly Moving Charge, General Derivation Radiation field far away from the charge (from e/d) Define andobtain:

24 Nonrelativistic case: Ultrarelativistic case:

25 We are looking for

26

27 Section 6. Homework Derive formula for the energy emitted by a rectilinearly moving charge in a given field in the nonrelativistic case.

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