Stabilizing Frequency of a Diode Laser to a Reference Transition of Molecular Iodine through Modulation Transfer Spectroscopy

Abstract: We report the frequency stabilization of an external cavity diode laser (ECDL) to a reference molecular iodine (I2) transition at 13,531.18 cm−1 (739.03382 nm). Using the Modulation Transfer Spectroscopy (MTS) method for the highly sensitive detection of weak absorption signals, the Doppler-free absorption peaks of I2 corresponding to the hot band transition R(78) (1–11) are resolved. The ECDL’s frequency is stabilized with respect to one of the lines lying within the reference absorption band. For this, the i… Show more

“…F. Yu et al [27] stabilized the distributed feedback (DFB) laser on the Cs absorption line. L. Sharma et al [28] selected the I 2 absorption line as the reference to achieve the frequency stabilization of the ECDL at 739 nm. B. Cheng et al [29] optimized the vapor temperature and the pump and probe light intensity to achieve a laser linewidth of 280 kHz.…”

Research on the Frequency Stabilization System of an External Cavity Diode Laser Based on Rubidium Atomic Modulation Transfer Spectroscopy Technology

“…F. Yu et al [27] stabilized the distributed feedback (DFB) laser on the Cs absorption line. L. Sharma et al [28] selected the I 2 absorption line as the reference to achieve the frequency stabilization of the ECDL at 739 nm. B. Cheng et al [29] optimized the vapor temperature and the pump and probe light intensity to achieve a laser linewidth of 280 kHz.…”

Research on the Frequency Stabilization System of an External Cavity Diode Laser Based on Rubidium Atomic Modulation Transfer Spectroscopy Technology

Advancing frequency locking: Modified FPGA-Guided direct modulation spectroscopy for laser stabilization