Title :
Microfabricated atomic magnetometers
Author :
Schwindt, P.D.D. ; Knappe, S. ; Shah, V. ; Liew, L.-A. ; Moreland, J.
Author_Institution :
Time & Frequency Div., NIST, Boulder, CO
fDate :
Oct. 30 2005-Nov. 3 2005
Abstract :
Using the techniques of microelectromechanical systems, we are developing chip-scale atomic sensors based on laser excitation of alkali atoms. Recently, we demonstrated a magnetometer physics package based on coherent population trapping that had a sensitivity of 50 pT/Hzfrac12 at 10 Hz, had a volume of 12 mm3, and used 195 mW of power as presented by Schwindt et al. (2004). To improve the sensitivity and reduce the power consumption of the magnetometer, we are evaluating other methods of interrogating the atoms for use in microfabricated devices. One of these methods uses frequency modulated nonlinear magneto-optical rotation (FM NMOR). We demonstrate that an FM NMOR magnetometer can be made to self-oscillate, offering simple construction and low power consumption
Keywords :
magneto-optical sensors; magnetometers; microsensors; 10 Hz; 195 mW; alkali atoms; chip-scale atomic sensors; frequency modulated magneto-optical rotation; laser excitation; microelectromechanical systems; microfabricated atomic magnetometers; nonlinear magneto-optical rotation; population trapping; Atom lasers; Atomic beams; Energy consumption; Frequency modulation; Laser excitation; Laser theory; Magnetic sensors; Magnetometers; Microelectromechanical systems; Sensor systems;
Conference_Titel :
Sensors, 2005 IEEE
Conference_Location :
Irvine, CA
Print_ISBN :
0-7803-9056-3
DOI :
10.1109/ICSENS.2005.1597640
