Title :
Frequency stabilization of lasers by locking to an atomic isoclinic point
Author :
Wells, N.P. ; Camparo, J.C.
Author_Institution :
Phys. Sci. Labs., Aerosp. Corp., El Segundo, CA, USA
Abstract :
To overcome the temperature sensitivity of lasers locked to Doppler-broadened transitions, we propose a scheme in which the laser is locked to an isoclinic point of the atom´s spectrum: a frequency at which the first derivative of the absorption spectrum does not change upon a physical change of the sample. Here, we demonstrate that an isoclinic point exists in the Rb87 D1 spectrum at 795 nm, and that it is located midway between the Fg=2 → Fe=1 and Fg=2 → Fe=2 transitions. Locking a VCSEL diode laser to this isoclinic point, we have been able to demonstrate a very low sensitivity of the locked laser´s frequency to temperature variations of the atomic vapor.
Keywords :
Doppler broadening; laser cavity resonators; laser frequency stability; laser mode locking; rubidium; semiconductor lasers; surface emitting lasers; Doppler-broadened transitions; Rb; VCSEL diode laser; absorption spectrum; atomic isoclinic point; lasers frequency stabilization; temperature sensitivity; Absorption; Atomic beams; Atomic clocks; Laser transitions; Resonant frequency; Sensitivity; Temperature sensors;
Conference_Titel :
Frequency Control Symposium (FCS), 2010 IEEE International
Conference_Location :
Newport Beach, CA
Print_ISBN :
978-1-4244-6399-2
DOI :
10.1109/FREQ.2010.5556317
