Title :
Chip Scale Atomic Magnetometers
Author :
Schwindt, P. ; Lindseth, B.J. ; Knappe, S. ; Shah, V. ; Liew, L. ; Moreland, J. ; Hollberg, L. ; Kitching, J.
Author_Institution :
NIST, Boulder
Abstract :
An optically pumped magnetometer was drastically miniaturized, by taking advantage of MEMS techniques, producing the chip-scale atomic magnetometers (CSAM) physics package. The key component of the package is an alkali vapor cell. To probe the magnetic field experienced by the atoms, the injection current to the VCSEL was modulated at 3.4 GHz near half the hyperfine frequency of 87Rb. Lock-in detection is used to determine the center of the resonance, and the magnetic field is determined by counting the modulation frequency, which is related to the Larmor precession frequency under these locked conditions. The ITO heaters create a large magnetic field gradient, which broadens the resonance and reduces the sensitivity.
Keywords :
magnetometers; micro-optomechanical devices; optical pumping; surface emitting lasers; ITO heaters; Larmor precession frequency; MEMS techniques; VCSEL; alkali vapor cell; chip-scale atomic magnetometers physics package; hyperfine frequency; injection current; lock-in detection; modulation frequency; optically pumped magnetometer; Atom optics; Frequency; Magnetic fields; Magnetic modulators; Magnetic resonance; Magnetometers; Micromechanical devices; Optical modulation; Optical pumping; Optical sensors;
Conference_Titel :
Magnetics Conference, 2006. INTERMAG 2006. IEEE International
Conference_Location :
San Diego, CA
Print_ISBN :
1-4244-1479-2
DOI :
10.1109/INTMAG.2006.376110
