Maxwell-Bloch Equations for a Laser

​
t
15.3
κ
-3.4
γ
1
3.54
γ
2
2.92
λ
0.34
e
0
0.62
p
0
0.9
d
0
1.45
In nonlinear optics, the Maxwell–Bloch equations can be used to describe laser systems. They consist of three first-order equations for the electric field in a single longitudinal cavity mode, which became nonlinear because the system oscillates between at least two discrete energy levels. The system is derived from Maxwell's equations, using semiclassical approximations for quantum variables. The equations are solved for population inversion density
D(t)
and mean atomic-polarization density
P(t)
, induced by an electric field
E(t)
. Here
κ
is the decay rate in the laser cavity due to beam transmission. The parameters
γ
1
and
γ
2
are decay rates of atomic polarization and population inversion and
λ
is a pumping energy parameter. Chaotic behavior and period doubling has been observed experimentally. These equations are related to the Lorenz equations and can exhibit strange attractors.

Details

The Maxwell–Bloch equations can be written as:

E
=κ(P-E)
,

P
=
γ
1
(ED-P)
,

D

γ
2
(λ+1-D-λEP)
.

References

[1] H. Haken, Light: Laser Light Dynamics, Vol. 2, New York: North-Holland Publishing Company, 1985.
[2] A. Scott (ed.), Encyclopedia of Nonlinear Science, New York: Routledge, 2005 pp. 564–566.

External Links

Chaos (Wolfram MathWorld)
Period Doubling (Wolfram MathWorld)
Quantum Mechanics (ScienceWorld)
Laser (ScienceWorld)
Polarization (ScienceWorld)
Maxwell Equations (ScienceWorld)
Electric Field (ScienceWorld)
Lorenz Attractor (Wolfram MathWorld)

Permanent Citation

Enrique Zeleny
​
​"Maxwell-Bloch Equations for a Laser"​
​http://demonstrations.wolfram.com/MaxwellBlochEquationsForALaser/​
​Wolfram Demonstrations Project​
​Published: December 11, 2014