Impact analysis of cavity length on transfer cavity frequency locking system for atomic inertial measurement device

Abstract: In this work, an efficient method for frequency stabilization of a highly off-resonant laser in a spin-exchange relaxation-free atomic inertial sensor is proposed. This was accomplished via the use of an optical resonator that transferred the stability of an atomic energy level to the laser frequency. The pump laser frequency was stabilized via saturation absorption spectroscopy and was used as a reference to lock the large-detuned probe laser with a double transmission Fabry–Pérot (FP) cavity. The frequency s… Show more

“…Moreover, when the cavity length decreased by 40%, the frequency stability of the system increased by approximately one order of magnitude. Furthermore, the cavity length and FSR were observed to be inversely and linearly proportional to the range of laser frequency detuning [21].…”

“…Moreover, when the cavity length decreased by 40%, the frequency stability of the system increased by approximately one order of magnitude. Furthermore, the cavity length and FSR were observed to be inversely and linearly proportional to the range of laser frequency detuning [21]. In 2019, Subhankar et al at NIST stabilized lasers at 556 and 798 nm through optical cavities [66].…”

“…Common resonant optical cavity-based frequency stabilization techniques include Pound-Drever-Hall (PDH) technique [15][16][17] and tilt-locking [18][19][20]. Moreover, a laser locking technique based on the transfer of the frequency stability from an F-P cavity is useful for applications that require stabilization of lasers at a large-detuned atomic-reference frequency [21]. Like a one-step reduction gear, the optical frequency combs can connect optically to different frequencies.…”

Far Off-Resonance Laser Frequency Stabilization Technology

“…Moreover, when the cavity length decreased by 40%, the frequency stability of the system increased by approximately one order of magnitude. Furthermore, the cavity length and FSR were observed to be inversely and linearly proportional to the range of laser frequency detuning [21].…”

“…Moreover, when the cavity length decreased by 40%, the frequency stability of the system increased by approximately one order of magnitude. Furthermore, the cavity length and FSR were observed to be inversely and linearly proportional to the range of laser frequency detuning [21]. In 2019, Subhankar et al at NIST stabilized lasers at 556 and 798 nm through optical cavities [66].…”

“…Common resonant optical cavity-based frequency stabilization techniques include Pound-Drever-Hall (PDH) technique [15][16][17] and tilt-locking [18][19][20]. Moreover, a laser locking technique based on the transfer of the frequency stability from an F-P cavity is useful for applications that require stabilization of lasers at a large-detuned atomic-reference frequency [21]. Like a one-step reduction gear, the optical frequency combs can connect optically to different frequencies.…”

Far Off-Resonance Laser Frequency Stabilization Technology

Transfer matrix analysis of the birefringent fiber Fabry–Perot cavity and laser frequency locking