Файл: Weber H., Herziger G., Poprawe R. (eds.) Laser Fundamentals. Part 1 (Springer 2005)(263s) PEo .pdf

Скачать файл (2,65Мб)

Заказать решение

ВУЗ: Не указан

Категория: Не указан

Дисциплина: Не указана

Добавлен: 28.06.2024

Просмотров: 857

Скачиваний: 0

ВНИМАНИЕ! Если данный файл нарушает Ваши авторские права, то обязательно сообщите нам.

6	1.1.2 The electromagnetic ﬁeld	[Ref. p. 40

For all quantities the complex notation is used [99Bor], the real quantities are Qreal = 12 (Q+Q ). The relations between D, E and B, H are given by the material equations. Under the action of an external electric/magnetic ﬁeld atomic or molecular electric/magnetic dipoles are generated in matter. The dipole moment per unit volume is called the electric or magnetic polarization P (E, H) or J (E, H), respectively. The resulting material quantities are the electric displacement D and the magnetic induction B given as:

D = ε0E + P (E, H) = ε0 ε(E, H) · E ,	(1.1.8)
B = µ0H + J (E, H) = µ0 µ(E, H) · H	(1.1.9)

with

P = ε0χe(E, H)E : electric polarization (SI-unit: As/m2),

J = µ0χm(E, H)H : magnetic polarization (SI-unit: Vs/m2),

χe(E, H), χm(E, H) : electric/magnetic susceptibility, in general a tensor and a function of the ﬁelds,

ε = 1 + χe, µ = 1 + χm : permittivity/permeability number, in general tensors, 1 : unit tensor,

ε0 = 8.8542 × 10−12 As/Vm: electric constant, µ0 = 4π × 10−7 Vs/Am: magnetic constant.

The current inside a medium is caused by the electric ﬁeld and Ohm’s law holds

j = σeE

(1.1.10)

with

σe: electric conductivity, in general a tensor and function of the ﬁeld, (SI-unit: A/Vm).

Electric and magnetic polarization depend in general on both generating ﬁelds, E and H. In many cases this relation is linear, but quite often a very complicated relation occurs, as in nonlinear optics, ferro-magnetism or ferro-electricity. The material equations can only be evaluated by quantum mechanics. In the following non-conducting (σe = 0), charge-free (ρ = 0) and nonmagnetic (χm = 0, µ = 1) media are assumed, which holds for dielectrics. The magnetic ﬁeld can be eliminated and a wave equation results from Maxwell’s equations:

grad div E − ∆E +				1 ∂2		E +	1	P	= 0 ,	(1.1.11)
grad div E − ∆E +				c02	∂t2	E +	ε0	P	= 0 ,	(1.1.11)
div D = 0										(1.1.12)
with
1						× 108 m/s : vacuum velocity of light .
c0 =			= 2.99792458
	√
	√	ε0µ0

Equation (1.1.11) is the fundamental equation, describing the propagation of optical ﬁelds. It includes di raction as well as ampliﬁcation of light and non-linear e ects. It has now to be adapted and simpliﬁed for the di erent applications in optics and laser technology.

1.1.2.2 Homogeneous, isotropic, linear dielectrics

The propagation of light in homogeneous media as gases, liquids, glasses or cubic crystals is investigated. These materials are assumed to be homogeneous (permittivity ε does not depend on the

Landolt-B¨ornstein

New Series VIII/1A1

Ref. p. 40]	1.1 Fundamentals of the semiclassical laser theory	7

spatial coordinates), isotropic (ε does not depend on the polarization of light), and linear (ε does not depend on the intensity of the ﬁeld). The last assumption holds for low-intensity ﬁelds only.

The permittivity ε is a scalar and (1.1.11)/(1.1.12) reduces to the standard wave equation:

∆E −	ε ∂2E		= 0 ,	(1.1.13)
	c02	∂t2
div E = 0 .				(1.1.14)

Simple solutions are the plane and the spherical waves.

1.1.2.2.1 The plane wave

The inﬁnite, monochromatic wave with a plane phase front and constant amplitude reads:

E = E0 exp[i(ωt − nk0r)] ,	(1.1.15)
H = H0 exp[i(ωt − nk0r)] ;	(1.1.16)

H0 = [k0 × E0] . k0Z

It is a transversely polarized ﬁeld with E H k0, as plotted in Fig. 1.1.3.


n = ε =			1 + χe :	the refractive index of the medium, in general complex,					(1.1.17)
k0 = 2π/λ0 : wave number in vacuum,
k0: wave vector, direction of propagation,
λ0: wavelength in vacuum,

	µµ0					µ0
Z =			: impedance,		Z0 =			= 376.7 Ω : vacuum impedance.
Z =		εε0	: impedance,		Z0 =		ε0	= 376.7 Ω : vacuum impedance.
The Poynting vector or energy ﬂux is a real quantity with
S = [Ereal × Hreal]				(SI-unit: W/m2).

(

[

6 N

]	Fig. 1.1.3. The plane wave in a homogeneous,
	isotropic medium.

Landolt-B¨ornstein

New Series VIII/1A1

8 1.1.2 The electromagnetic ﬁeld [Ref. p. 40

Table 1.1.1. Values of refractive index nr and absorption coe cient α at wavelength λ0 [85Pal, 82Gra, 78Dri].

Material	λ0 [µm]	nr	α [m−1]
Fused quartz	0.54	1.46	very small
Sapphire	0.50	1.765/1.764	very small
Water	0.54	1.332	0.8
Water	1	1.328	80	6
Copper	0.54	0.7		6
Copper	0.54	0.7	11.6 × 106
Gold	0.54	0.3	11.1	× 106
Iron	0.54	2.4	16.4	× 10

The intensity is the time average over one period T = 2π/ω and results in:

J = S

(1.1.18)

4 Z Z

For dielectrics without losses (µ = 1, n = nr is real), (1.1.18) reduces to

J =

c0nrε0

|E0

(1.1.19)

with both quantities, E0 and J , inside the medium. For vacuum applies

JW/m2 = 1.33 × 10−3

E0,V/m

= 27.4

JW/m2

For a homogeneous dielectric, low-absorbing

medium the complex refractive index is given by

[99Bor, p. 739]:

nˆ = nr − i

α k0

(1.1.20)

2k0

with

nr: real part of the refractive index,

α: absorption coe cient, in general the non-resonant broad-band absorption.

For a ﬁeld propagating in z-direction (1.1.15)/(1.1.20) deliver an exponentially damped ampli-

tude:
E(z, t) = E0 exp i(ωt − nrk0z) −	αz	.	(1.1.21)
	2

Some numbers of nr, α are compiled in Table 1.1.1.

1.1.2.2.2 The spherical wave

One solution of the wave equation (1.1.13) in spherical coordinates is the quasi-spherical wave, generated by an oscillating dipole (Hertz’s dipole), see Fig. 1.1.4. The far ﬁeld reads [99Jac]:

E (r, ϑ, t) =

λ0Eϑ

exp [i (ωt

−

nˆk

r)] sin ϑ ,

ϑ|

|µ| 4π2k03

, r

ε0

with µ the dipole moment and ϑ the angle between the dipole axis and beam propagation k0.

In the paraxial approach (ϑ π/2 , θ 1) the well-known spherical wave, useful for applying

Huygens’ principle, results:

λ0	E0 exp [i (ωt − nˆk0r)] , θ 1 ,
E(z, t) = r	E0 exp [i (ωt − nˆk0r)] , θ 1 ,	(1.1.22)

where E is approximately parallel to the dipole axis.

Landolt-B¨ornstein

New Series VIII/1A1

Ref. p. 40]	1.1 Fundamentals of the semiclassical laser theory	9

r, S, k0

z	Fig. 1.1.4. A quasi-spherical wave, emitted by an
	oscillating dipole.

1.1.2.2.3 The slowly varying envelope (SVE) approximation

In the Slowly Varying Envelope approximation (1.1.11) is solved approximately with the ansatz of a quasi-monochromatic, quasi-plane wave

E = E0(x, y, z, t) exp[i(ωt − nrk0z)] , P = P 0(x, y, z, t) exp[i(ωt − nrk0z)] .

(1.1.23)

The wave propagates mainly in z-direction and the amplitude is slowly varying with x, y, z, t, which means:

–slowly varying in time (quasi-monochromatic): ∂|E0|/∂t ω|E0|, or spectral bandwidth ∆ω ω,

–slowly varying in space (quasi-plane wave): ∂|E0|/∂z k0|E0|, which means low divergence of the beam ∆θ 1 (paraxial approach), and a smooth transverse proﬁle,

–slowly varying polarization ∂|P 0|/∂t ω|P 0|,

–slowly varying electric susceptibility ∂|χe|/∂t ω|χe| and |grad χe| k0|χe|.

Then second order terms can be neglected and the SVE-approximations are obtained [84She, p. 47], [66War, 86Sie].

1.1.2.2.4 The SVE-approximation for di raction

Steady-state propagation in vacuum means ∂|E0|/∂t = 0 and P = 0. Equation (1.1.11) delivers with the ansatz (1.1.23) and neglecting ∂2E0/∂t2 the SVE-approximation used in di raction theory, also called the Schr¨odinger equation of optics:


∆tr − 2ik0				∂	E0	= 0 ,	div E = 0 .	(1.1.24a)
			∂z
∆tr is the transverse delta-operator, which in rectangular coordinates reads
∆tr =	∂2	+		∂2	.
	∂x2			∂y2

The ﬁeld in (1.1.24a) is a vector ﬁeld, and the ∆-operator in cylinder coordinates is rather complicated, because the unit-vectors are no longer constant [99Jac], especially for non-uniform polarization in circular birefringent media [82Fer, 93Wit]. In most cases (except birefringence) the

Landolt-B¨ornstein

New Series VIII/1A1