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Autores principales: Chistolini, Trevor, Lee, Kyunghoon, Banerjee, Archan, Alghadeer, Mohammed, Jünger, Christian, Altoé, M. Virginia P., Song, Chengyu, Chen, Sudi, Wang, Feng, Santiago, David I., Siddiqi, Irfan
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2405.01784
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author Chistolini, Trevor
Lee, Kyunghoon
Banerjee, Archan
Alghadeer, Mohammed
Jünger, Christian
Altoé, M. Virginia P.
Song, Chengyu
Chen, Sudi
Wang, Feng
Santiago, David I.
Siddiqi, Irfan
author_facet Chistolini, Trevor
Lee, Kyunghoon
Banerjee, Archan
Alghadeer, Mohammed
Jünger, Christian
Altoé, M. Virginia P.
Song, Chengyu
Chen, Sudi
Wang, Feng
Santiago, David I.
Siddiqi, Irfan
contents Suspending devices on thin SiN membranes can limit their interaction with the bulk substrate and reduce parasitic capacitance to ground. While suspending devices on membranes is used in many fields including radiation detection using superconducting circuits, there has been less investigation into maximum membrane aspect ratios and achievable suspended device quality, metrics important to establish the applicable scope of the technique. Here, we investigate these metrics by fabricating superconducting coplanar waveguide resonators entirely atop thin ($\sim$110 nm) SiN membranes, where the membrane's shortest length to thickness yields an aspect ratio of approximately $7.4 \times 10^3$. We compare these membrane resonators to on-substrate resonators on the same chip, finding similar internal quality factors $\sim$$10^5$ at single photon levels. Furthermore, we confirm that these membranes do not adversely affect resonator thermalization and conduct further materials characterization. By achieving high quality superconducting circuit devices fully suspended on thin SiN membranes, our results help expand the technique's scope to potential uses including incorporating higher aspect ratio membranes for device suspension and creating larger footprint, high impedance, and high quality devices.
format Preprint
id arxiv_https___arxiv_org_abs_2405_01784
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Performance of Superconducting Resonators Suspended on SiN Membranes
Chistolini, Trevor
Lee, Kyunghoon
Banerjee, Archan
Alghadeer, Mohammed
Jünger, Christian
Altoé, M. Virginia P.
Song, Chengyu
Chen, Sudi
Wang, Feng
Santiago, David I.
Siddiqi, Irfan
Quantum Physics
Applied Physics
Suspending devices on thin SiN membranes can limit their interaction with the bulk substrate and reduce parasitic capacitance to ground. While suspending devices on membranes is used in many fields including radiation detection using superconducting circuits, there has been less investigation into maximum membrane aspect ratios and achievable suspended device quality, metrics important to establish the applicable scope of the technique. Here, we investigate these metrics by fabricating superconducting coplanar waveguide resonators entirely atop thin ($\sim$110 nm) SiN membranes, where the membrane's shortest length to thickness yields an aspect ratio of approximately $7.4 \times 10^3$. We compare these membrane resonators to on-substrate resonators on the same chip, finding similar internal quality factors $\sim$$10^5$ at single photon levels. Furthermore, we confirm that these membranes do not adversely affect resonator thermalization and conduct further materials characterization. By achieving high quality superconducting circuit devices fully suspended on thin SiN membranes, our results help expand the technique's scope to potential uses including incorporating higher aspect ratio membranes for device suspension and creating larger footprint, high impedance, and high quality devices.
title Performance of Superconducting Resonators Suspended on SiN Membranes
topic Quantum Physics
Applied Physics
url https://arxiv.org/abs/2405.01784