Generation of Coherent Phonons via a Cavity Enhanced Photonic Lambda Scheme.

J. Bourhill, N. Carvalho, M. Goryachev, S. Galliou, M. Tobar
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引用次数: 1

Abstract

We demonstrate the generation of coherent phonons in a quartz Bulk Acoustic Wave (BAW) resonator through the photoelastic properties of the crystal, via the coupling to a microwave cavity enhanced by a photonic lambda scheme. This is achieved by imbedding a single crystal BAW resonator between the post and the adjacent wall of a microwave reentrant cavity resonator. This 3D photonic lumped LC resonator at the same time acts as the electrodes of a BAW phonon resonator, and allows the direct readout of coherent phonons via the linear piezoelectric response of the quartz. A microwave pump, $\omega_p$ is tuned to the cavity resonance $\omega_0$, while a probe frequency, $\omega_{probe}$, is detuned and varied around the red and blue detuned values with respect to the BAW phonon frequency, $\Omega_m$. The pump and probe power dependence of the generated phonons unequivocally determines the process to be electrostrictive, with the phonons produced at the difference frequency between pump and probe, with no back action effects involved. Thus, the phonons are created without threshold and can be considered analogous to a Coherent Population Trapped (CPT) maser scheme.
通过腔增强光子λ方案产生相干声子。
我们演示了通过晶体的光弹性特性,通过光子λ方案增强的微波腔的耦合,在石英体声波(BAW)谐振器中产生相干声子。这是通过在微波重入腔谐振器的柱和相邻壁之间嵌入单晶BAW谐振器来实现的。这种三维光子集总LC谐振器同时充当BAW声子谐振器的电极,并允许通过石英的线性压电响应直接读出相干声子。一个微波泵$\omega_p$被调谐到腔共振$\omega_0$,而一个探针频率$\omega_{probe}$被调谐,并在相对于BAW声子频率$\Omega_m$的红色和蓝色调谐值周围变化。所产生的声子对泵和探头功率的依赖性明确地决定了该过程是电致伸缩的,声子以泵和探头之间的不同频率产生,没有涉及反作用效应。因此,声子的产生没有阈值,可以被认为类似于相干种群捕获(CPT)脉泽方案。
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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