Quench dynamics of Wannier-Stark states in an active synthetic photonic lattice

arXiv - PHYS - Pattern Formation and Solitons Pub Date : 2024-05-08 DOI:arxiv-2405.04774

Alexander Dikopoltsev, Ina Heckelmann, Mathieu Bertrand, Mattias Beck, Giacomo Scalari, Oded Zilberberg, Jerome Faist

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Abstract

Photonic emulators have facilitated the investigation of numerous solid-state phenomena and have contributed to the development of optical devices inspired by quantum mechanics. Although current photonic emulators are constrained to bosonic behavior with local interactions, the utilization of active synthetic lattices holds promise for surpassing these limitations. In this study, we propose employing the modulated ring fast-gain laser as a foundation for emulating quench dynamics within a synthetic lattice that conforms to equal density filling of its reciprocal space. To illustrate the effectiveness of this emulation platform, we subject a dispersed Wannier-Stark ladder to quenching and directly observe oscillations, enabled by the fast-gain, along with their coherent stabilization to a single Wannier stark state. These coherent dynamics stem directly from our lasers liquid state of light, a characteristic resulting from fast-gain and explained by the rapid decay of fluctuations occurring on the system's shortest timescale. Additionally, by adequately biasing the lattice through detuning the modulation from the cavity resonance, this process supports oscillatory dynamics within the synthetic space.

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有源合成光子晶格中万尼尔-斯塔克态的淬火动力学

光子模拟器促进了对许多固态现象的研究，并推动了受量子力学启发的光学设备的发展。虽然目前的光子模拟器受限于具有局部相互作用的玻色行为，但利用有源合成晶格有望突破这些限制。在这项研究中，我们提出利用调制环快增益激光器作为基础，在符合等密度填充其倒数空间的合成晶格内模拟淬火动力学。为了说明这一仿真平台的有效性，我们对分散的万尼尔-斯塔克梯形图进行了淬火，并直接观察到了快速增益所产生的振荡，以及它们在单一万尼尔-斯塔克状态下的相干稳定。这些相干动力学直接源于我们的激光器的液态光，这是快速增益带来的一个特征，也是在系统最短时间尺度上发生的波动快速衰减的原因。此外，通过对空腔共振进行失谐调制来适当偏置晶格，这一过程支持合成空间内的振荡动力学。

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arXiv - PHYS - Pattern Formation and Solitons

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