Interpretation of Superradiant Ramsey Spectroscopy in a Coherent Picture Based on Transverse Spins Superposition
- URL: http://arxiv.org/abs/2503.11580v1
- Date: Fri, 14 Mar 2025 16:46:45 GMT
- Title: Interpretation of Superradiant Ramsey Spectroscopy in a Coherent Picture Based on Transverse Spins Superposition
- Authors: Ke-Xin Gao, Yuan Zhang, Shi-Lei Su, Gang Chen, Chongxin Shan, Klaus Mølmer,
- Abstract summary: Recent experiments demonstrated Ramsey spectroscopy with delayed superradiance of strontium-88 atoms transversely excited by a laser pulse.<n>We introduce two complementary pictures by considering the in-phase and out-phase superposition of the transverse collective spin operators of two atomic sub-ensembles.<n>Our simulations suggest that a coherent picture of the whole atomic ensemble can only be established by employing different pictures for the dynamics associated with the external driving.
- Score: 6.440392138973035
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Recent experiments demonstrated Ramsey spectroscopy with delayed superradiance of strontium-88 atoms transversely excited by a laser pulse [Nat. Commun. 15, 1084 (2024)]. To illustrate the physics involved, we introduce two complementary pictures by considering the in-phase and out-phase superposition of the transverse collective spin operators of two atomic sub-ensembles, and analyze the dynamics of the whole ensemble with the Dicke states and the collective Bloch vector. Our simulations suggest that a coherent picture of the whole atomic ensemble can only be established by employing different pictures for the dynamics associated with the external driving and the cavity-mediated superradiance, and then mapping the two pictures at the end of the external driving. In the future, the pictures as developed here can be utilized to analyze in more detail the dependence of the superradiance on the relative phase of the couplings and the number of atomic sub-ensembles, and the mechanism as revealed here can be explored to study other interesting phenomena, such as weak-to-strong coupling phase transition, triggered superradiance, and quantum measurement effects.
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