Analytical and numerical study of light-induced optical microcavity generation by half-cycle light pulses in the resonant medium

Rostislav Arkhipov, Anton Pakhomov, Olga Diachkova, Mikhail Arkhipov, Nikolay Rosanov
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Abstract

An optical Bragg-like microcavity can be formed when extremely short light pulses interacting coherently with the medium collide in the resonant medium. Here we present an analytical approach, based on the approximate solution of the time-dependent Schrödinger equation, that reveals both the cavity formation and its control by the half-cycle pulses colliding in the medium. This approach allows the calculation of cavity properties in the weak-field regime without the need for complex numerical simulations. Beyond the approximate analytical solutions, our analytical results are confirmed by numerical simulations of the Maxwell-Bloch equations. Grating formation is also studied in the strong-field regime, where collisions of self-induced transparency half-cycle pulses occur. The results presented here reveal, to our knowledge, a new type of spatio-temporal photonic crystal in the form of micro-cavities in a simple atomic medium. The results obtained demonstrate the feasibility of attosecond optical switching in a simple atomic medium with half-cycle pulses.
共振介质中的半周期光脉冲光诱导微腔生成的分析和数值研究
当与介质发生相干作用的极短光脉冲在共振介质中碰撞时,就会形成类似布拉格的光学微腔。在此,我们提出了一种基于随时间变化的薛定谔方程近似解的分析方法,该方法揭示了空腔的形成以及介质中碰撞的半周期脉冲对其的控制。这种方法可以计算出弱场下的空腔特性,而无需进行复杂的数值模拟。除了近似分析解之外,我们的分析结果还得到了 Maxwell-Bloch 方程数值模拟的证实。光栅的形成也是在强场机制下研究的,在强场机制下会发生自诱导透明半周期脉冲的碰撞。据我们所知,本文介绍的结果揭示了一种在简单原子介质中以微腔形式存在的新型时空光子晶体。所获得的结果证明了在简单原子介质中利用半周期脉冲进行阿秒光学开关的可行性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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