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    Area of Science:

    • Atomic, Molecular, and Optical (AMO) Physics
    • Laser Spectroscopy
    • Quantum Technologies

    Background:

    • Modulation Transfer Spectroscopy (MTS) is a precise laser locking technique.
    • Traditional MTS is limited to closed atomic transitions due to its reliance on four-wave mixing.
    • This limitation excludes MTS from numerous important AMO physics applications.

    Purpose of the Study:

    • To report the first observation of a magnetically tunable MTS error signal.
    • To overcome the limitations of traditional MTS for laser frequency stabilization.
    • To expand the applicability of MTS to a wider range of atomic and molecular resonances.

    Main Methods:

    • Utilized a simple two-magnet arrangement to induce Zeeman shifts.
    • Applied magnetic fields to tune the MTS error signal for Rubidium-87 (Rb87).
    • Demonstrated tunability over a range exceeding 15 GHz on the Rb87 D2 spectrum.

    Main Results:

    • Successfully observed a magnetically tunable MTS error signal for the first time.
    • Achieved Zeeman-shifting of the error signal for the Rb87 F=2→F'=3 cooling transition.
    • Demonstrated MTS signals for locking to the Rb87 F=1→F'=2 repumping transition and a detuned cooling transition.

    Conclusions:

    • The developed technique enables laser locking to arbitrary points on the rubidium D2 spectrum.
    • This magnetically tunable MTS method significantly broadens the scope of laser stabilization applications.
    • The technique is readily extendable to locking Raman and lattice lasers, enhancing precision in AMO experiments.