Related papers: High-Q cavity coupled to a high permittivity dielectric resonator for sensing applications

High-Q cavity coupled to a high permittivity dielectric resonator for sensing applications

URL: http://arxiv.org/abs/2410.05831v2
Date: Thu, 16 Jan 2025 08:56:43 GMT
Title: High-Q cavity coupled to a high permittivity dielectric resonator for sensing applications
Authors: Shahnam Gorgi Zadeh, Alberto Ghirri, Sergio Pagano, Simone Tocci, Claudio Gatti, Antonio Cassinese,
Abstract summary: We report on a coupled cavity configuration in which a superconducting cavity is coupled with a high permittivity. We discuss a specific application of the coupled system as a bolometer in different temperature ranges.
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Abstract: The use of high quality factor resonators is of undoubted interest for high precision measurements and for applications in quantum technologies. Novel types of microwave sensors can be realized by coupling a first resonator acting as a stable frequency reference with a second resonator that is sensitive to a particular physical quantity. Here we report on a coupled cavity configuration in which a high $Q$-factor elliptical TESLA-shaped superconducting cavity is coupled with a high permittivity ($\varepsilon_\mathrm{r}$) SrTiO$_3$ puck, whose resonant frequency varies as a function of temperature due to the temperature dependence of the permittivity that reaches values higher than 30000 below 1 K. Extensive electromagnetic simulations are used to test different coupling configurations, showing great versatility to tune the coupling in the weak or strong regime, depending on the puck's position within the cavity. Moreover, for the coupled system, they allow one to investigate the dependence of the zero transmission frequency value on changes of the permittivity $\varepsilon_\mathrm{r}$, obtaining a maximum value of 2.8 MHz per unit change of $\varepsilon_\mathrm{r}$, for $\varepsilon_\mathrm{r} \approx 230$. Finally, we discuss a specific application of the coupled system as a bolometer in different temperature ranges.

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