Dielectric Haloscopes as Gravitational Wave Detectors

arXiv - PHYS - High Energy Physics - Phenomenology Pub Date : 2024-09-10 DOI:arxiv-2409.06462

Valerie Domcke, Sebastian A. R. Ellis, Joachim Kopp

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引用次数: 0

Abstract

We argue that dielectric haloscopes like MADMAX, originally designed for detecting axion dark matter, are also very promising gravitational wave detectors. Operated in resonant mode at frequencies around $\mathcal{O}(10\,\text{GHz})$, these detectors benefit from enhanced gravitational wave to photon conversion at the surfaces of a stack of thin dielectric disks. Since the gravitational wave is relativistic, there is an additional enhancement of the signal compared to the axion case due to increased conversion probability of gravitational waves to photons in the vacuum between the disks. A gravitational wave search using a dielectric haloscope imposes stringent requirements on the disk thickness and placement, but relaxed requirements on the disk smoothness. An advantage is the possibility of a broadband or hybrid resonant/broadband operation mode, which extends the frequency range down to $\mathcal{O}(100\,\text{MHz})$. We show that strain sensitivities down to $10^{-21} \text{Hz}^{-1/2} \times (10\,\text{GHz}/f)$ will be possible in the coming years for the broadband setup, while a resonant setup optimized for gravitational waves could even reach $3\times 10^{-23} \text{Hz}^{-1/2} \times (10\,\text{GHz}/f)$ with current technology.

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作为引力波探测器的介质卤镜

我们认为，像MADMAX这样的介电半透镜，最初是为探测轴心暗物质而设计的，也是非常有前途的引力波探测器。这些探测器在大约$\mathcal{O}(10\,\text{GHz})$的频率下以谐振模式工作，得益于在厚电介质盘堆叠表面上增强的引力波到光子的转换。由于引力波是相对论性的，在磁盘之间的真空中引力波到光子的转换概率增加，因此与轴心情况相比，信号会有额外的增强。使用富介电镜进行引力波搜索对磁盘的厚度和位置有严格要求，但对磁盘的光滑度要求较松。其优点是可以采用宽带或混合谐振/宽带工作模式，从而将频率范围扩展到 $\mathcal{O}(100\\text{MHz})$ 。我们的研究表明，应变灵敏度可低至 10^{-21} 美元。\而针对引力波进行优化的谐振装置甚至可以达到 $\times 10^{-23} （10^{Hz}^{-1/2}/f）$。而针对引力波进行了优化的谐振装置甚至可以在现有技术条件下达到3美元/次（10^{-23}\text{Hz}^{-1/2}\times (10\\text{GHz}/f)$ ）。

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arXiv - PHYS - High Energy Physics - Phenomenology

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