APPLETON-HARTREE EQUATION

The 'Appleton-Hartree equation', sometimes also referred to as the 'Appleton-Lassen equation' is a mathematical expression that describes the refractive index for electromagnetic wave propagation in a cold magnetized plasma. The Appleton-Hartree equation was developed independently by several different scientists, including Edward Victor Appleton, Douglas Hartree and K. Lassen.

Equation

Full Equation

The equation is typically given as follows ^[1]:
:

n^2 = 1 - rac{X}{1 - iZ - rac{rac{1}{2}Y^2sin^2	heta}{1 - X - iZ} pm rac{1}{1 - X - iZ}left(rac{1}{4}Y^4sin^4	heta + Y^2cos^2	hetaleft(1 - X - iZ
ight)^2
ight)^{1/2}}

Definition of Terms

n

= complex refractive index

i

sqrt{-1}

X = rac{omega_0^2}{omega^2}

Y = rac{omega_H}{omega}

Z = rac{
u}{omega}

u

= electron collision frequency

omega = 2pi f

f

= wave frequency

omega_0 = 2pi f_0 = sqrt{rac{Ne^2}{epsilon_0 m}}

= electron plasma frequency

omega_H = 2pi f_H = rac{B_0 |e|}{m}

= electron gyro frequency

epsilon_0

= permittivity of free space

mu_0

= permeability of free space

B_0

= ambient magnetic field strength

e

= electron charge

m

= electron mass

heta

= angle between the ambient magnetic field vector and the wave vector

Modes of Propagation

The presence of the

pm

sign in the Appleton-Hartree equation gives two separate solutions for the refractive index ^[1]. For propagation parallel to the magnetic field, i.e.,

kparallel B_0

, the '+' sign represents the "ordinary mode," and the '-' sign represents the "extraordinary mode." For propagation perpendicular to the magnetic field, i.e.,

kperp B_0

, the '+' sign represents a left-hand circularly polarized mode, and the '-' sign represents a right-hand circularly polarized mode. See the article on electromagnetic electron waves for more detail.

Reduced Forms

Propagation in a Collisionless Plasma

If the wave frequency of interest

omega

is much smaller than the electron collision frequency

u

, the plasma can be said to be "collisionless." That is, given the condition

u ll omega

,
we have

Z = rac{
u}{omega} ll 1

,
so we can neglect the

Z

terms in the equation. The Appleton-Hartree equation for a cold, collisionless plasma is therefore,
:

n^2 = 1 - rac{X}{1 - rac{rac{1}{2}Y^2sin^2	heta}{1 - X} pm rac{1}{1 - X}left(rac{1}{4}Y^4sin^4	heta + Y^2cos^2	hetaleft(1 - X
ight)^2
ight)^{1/2}}

Quasi-Longitudinal Propagation in a Collisionless Plasma

If we further assume that the wave propagation is primarily in the direction of the magnetic field, i.e.,

heta pprox 0

, we can neglect the

Y^4sin^4	heta

term above. Thus, for quasi-longitudinal propagation in a cold, collisionless plasma, the Appleton-Hartree equation becomes,
:

n^2 = 1 - rac{X}{1 - rac{rac{1}{2}Y^2sin^2	heta}{1 - X} pm Ycos	heta}

References

;Citations and notes
1.
2.

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APPLETON-HARTREE EQUATION

Equation

Full Equation

Definition of Terms

Modes of Propagation

Reduced Forms

Propagation in a Collisionless Plasma

Quasi-Longitudinal Propagation in a Collisionless Plasma

References

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