Title :
Thermal effects in doped fibers
Author :
Davis, M.K. ; Digonnet, M.J.F. ; Pantell, Richard H.
Author_Institution :
Edward L. Ginzton Lab., Stanford Univ., CA, USA
fDate :
6/1/1998 12:00:00 AM
Abstract :
A theoretical analysis of the pump-induced temperature change and associated thermal phase shift occurring in a pumped doped fiber is presented. Although the primary devices targeted are all-optical switches based on doped fibers, where such effects can be detrimental, this analysis is also applicable to lasers, amplifiers, and other doped fiber devices. The effects of a single pump pulse, multiple pulses and continuous wave (CW) pumping are investigated, both in the dynamic and steady-state regimes. Simple expressions are derived for the thermal relaxation time constant of a fiber, and for its steady-state temperature rise and thermal phase shift under CW pumping. This study predicts that in all-optical fiber switches utilizing a reasonably good dopant the thermal effect due to a single short pulse is negligible in all interferometers, while the steady-state effect can be sizable in a standard fiber Mach-Zehnder but is negligible in a twin-core fiber, a two-mode fiber, and a specially designed Mach-Zehnder interferometer
Keywords :
Mach-Zehnder interferometers; optical fibre theory; optical pumping; optical switches; stability; CW pumping; Mach-Zehnder interferometer; all-optical fiber switches; all-optical switches; doped fiber devices; doped fiber thermal effects; multiple pulses; primary devices; pump-induced temperature change; pumped doped fiber; reasonably good dopant; single short pulse; standard fiber Mach-Zehnder; steady-state regimes; steady-state temperature rise; thermal effect; thermal phase shift; thermal relaxation time constant; twin-core fiber; two-mode fiber; Doped fiber amplifiers; Fiber lasers; Laser theory; Mach-Zehnder interferometers; Optical fiber devices; Pulse amplifiers; Pump lasers; Steady-state; Switches; Temperature;
Journal_Title :
Lightwave Technology, Journal of
