Title :
Sensitivity and stability of a radiation-balanced laser system
Author :
Bowman, Steven R. ; Jenking, N.W. ; O´Connor, S.R. ; Feldman, Barry J.
Author_Institution :
Photonics Technol. Branch, US Naval Res. Lab., Washington, DC, USA
fDate :
10/1/2002 12:00:00 AM
Abstract :
It has been previously shown that it is theoretically possible to build a solid-state laser that generates no internal heat. This is accomplished through a detailed balance of the stimulated and spontaneous emission. Such a device is called a radiation-balanced laser. Here, we analyze laser operation when conditions deviate from perfect balance. Sensitivity and stability analyses are presented for perturbations in the field parameters and temperature. We show that the radiation balance is a stable equilibrium under both transient and steady-state perturbations. Limits are derived on the magnitude of allowable spatial perturbations, and techniques for spatial mode matching are discussed. Numerical simulations of 1-μm laser operation of Yb-doped potassium gadolinium tungstate are provided as an example.
Keywords :
Stark effect; fluorescence; laser modes; laser stability; laser theory; perturbation theory; solid lasers; spontaneous emission; stimulated emission; ytterbium; KGd(WO4)2:Yb; Stark splitting; allowable spatial perturbations; emission balance; field parameter perturbations; fluorescence cooling; laser sensitivity; laser stability; laser thermal factors; quantum defect heating; quasi-two-level laser system; radiation-balanced laser system; radiative lifetime; solid-state laser; spatial mode matching; spontaneous emission; steady-state perturbations; stimulated emission; temperature perturbations; thermally isolated laser crystals; transient perturbations; zero net quantum defect; Cooling; Laser modes; Laser noise; Laser stability; Laser theory; Laser transitions; Pump lasers; Solid lasers; Stimulated emission; Thermal stresses;
Journal_Title :
Quantum Electronics, IEEE Journal of
DOI :
10.1109/JQE.2002.802950
