The adiabatic elimination principle [91, 92] is universal in the area of nonlinear dissipative dynamical systems, and its importance arises from the fact that it allows one to reduce the number of the equations which govern the dynamics of the system. We introduce it at this stage in the book in order to be able to describe the optical pumping mechanisms which can be exerted to attain population inversion. However, this principle will be applied repeatedly in the following chapters for other purposes.

In the first subsection we describe the principle in general, while the following subsections concern the issue of optical pumping. We show first that it is not possible to obtain population inversion between the two levels of the lasing transition if the pump involves only these two levels. Next we illustrate the three-level pumping scheme and the four-level pumping scheme. We demonstrate that, by adiabatically eliminating the probabilities of the additional energy levels, one arrives at an equation identical to Eq. (4.12), which, for appropriate ranges of values of the parameters involved in the pumping, allows one to obtain population inversion.

General formulation of the principle

In a dissipative dynamical system the dynamical variables undergo relaxation processes associated with suitable rate constants such as, for example, the rate γ⊥ for the normalized atomic polarization P and the rate γ∥ for the normalized population difference D. The inverses of these rates provide the time scales which characterize the evolution of each variable. Therefore we can distinguish a set of fast variables, which evolve over short time scales and are therefore characterized by large relaxation rates, and a set of slow variables, which display small relaxation rates. A remarkable simplification in the analysis of dynamical systems is obtained by using the technique of adiabatic elimination of fast variables, which Haken considered as a basis for the discipline which he formulated and called Synergetics [91, 92].