Coherence-Assisted Superradiant Laser with Hz Linewidth and 10-10W Power
Abstract
The superradiant laser, based on the clock transition between the electric ground state 1S0 and the metastable state 3P0 of fermionic alkaline-earth(-like) atoms, has been proposed to be a new promising light source with linewidth being the order of millihertz. However, due to the small 1S0-to-3P0 transition strength, the steady-state power in that system is relatively low ( 10-12W). In this work, we propose an alternative superradiant laser scheme based on a Raman-transition-induced coupling between the 3P0 and 3P1 states in bosonic alkaline-earth(-like) atoms, and achieve a laser with linewidth 2π×1Hz and power 10-10W ( 103 photons in steady state) at a small pumping cost. The Raman beams play two significant roles in our scheme. First, the coherence between the dark and bright states induced by the Raman beams produce a new local minimum in the pumping-linewidth curve with pumping rate lower than 2π × 10kHz, which is beneficial for continuous output. Second, the Raman beams mix the long-lived 3P0 state into the lasing state and thus reduce the linewidth. Our work greatly improves the output performance of the superradiant laser system with coherence induced by Raman transitions and may offer a firm foundation for its practical use in future.
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