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Main Authors: Shan, Wenelei, Ezaki, Shohei
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.08157
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author Shan, Wenelei
Ezaki, Shohei
author_facet Shan, Wenelei
Ezaki, Shohei
contents Tow-level system (TLS) loss in amorphous dielectric materials has been intensively studied at millikelvin temperatures due to its impact on superconducting qubit devices and incoherent detectors. However, the significance of TLS loss in superconducting transmission lines at liquid helium temperatures remains unclear. This study investigates TLS loss in amorphous $SiO_2$ at liquid helium temperatures (about 4 K) within a frequency range of 130-170 GHz, using niobium microstrip and coplanar waveguide resonators. Our results demonstrate notable power and temperature dependence of dielectric loss, with the dielectric loss and quasiparticle loss exchanging dominance at around 4 K. These findings are consistent with TLS models and provide crucial insights for the design of superconducting devices operating at liquid helium temperatures.
format Preprint
id arxiv_https___arxiv_org_abs_2407_08157
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Two-level System Loss: significant not only at Millikelvin
Shan, Wenelei
Ezaki, Shohei
Instrumentation and Methods for Astrophysics
Tow-level system (TLS) loss in amorphous dielectric materials has been intensively studied at millikelvin temperatures due to its impact on superconducting qubit devices and incoherent detectors. However, the significance of TLS loss in superconducting transmission lines at liquid helium temperatures remains unclear. This study investigates TLS loss in amorphous $SiO_2$ at liquid helium temperatures (about 4 K) within a frequency range of 130-170 GHz, using niobium microstrip and coplanar waveguide resonators. Our results demonstrate notable power and temperature dependence of dielectric loss, with the dielectric loss and quasiparticle loss exchanging dominance at around 4 K. These findings are consistent with TLS models and provide crucial insights for the design of superconducting devices operating at liquid helium temperatures.
title Two-level System Loss: significant not only at Millikelvin
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2407.08157