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Main Authors: Hedrick, Elizabeth, Bahrami, Faranak, Pakpour-Tabrizi, Alexander C., Joshi, Atharv, Rahman, Q. Rumman, Yang, Ambrose, Chang, Ray D., Bland, Matthew P., Jindal, Apoorv, Cheng, Guangming, Yao, Nan, Cava, Robert J., Houck, Andrew A., de Leon, Nathalie P.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.13183
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author Hedrick, Elizabeth
Bahrami, Faranak
Pakpour-Tabrizi, Alexander C.
Joshi, Atharv
Rahman, Q. Rumman
Yang, Ambrose
Chang, Ray D.
Bland, Matthew P.
Jindal, Apoorv
Cheng, Guangming
Yao, Nan
Cava, Robert J.
Houck, Andrew A.
de Leon, Nathalie P.
author_facet Hedrick, Elizabeth
Bahrami, Faranak
Pakpour-Tabrizi, Alexander C.
Joshi, Atharv
Rahman, Q. Rumman
Yang, Ambrose
Chang, Ray D.
Bland, Matthew P.
Jindal, Apoorv
Cheng, Guangming
Yao, Nan
Cava, Robert J.
Houck, Andrew A.
de Leon, Nathalie P.
contents The recent realization of millisecond-scale coherence with tantalum-on-silicon transmon qubits showed that depositing the Al/AlOx/Al Josephson junction in a high purity, ultrahigh vacuum environment was critical for achieving lifetime-limited coherence, motivating careful examination of the aluminum surface two-level system (TLS) bath. Here, we measure the microwave absorption arising from surface TLSs in superconducting aluminum resonators, following methodology developed for tantalum resonators. We vary film and surface properties and correlate microwave measurements with materials characterization. We find that the lifetimes of superconducting aluminum resonators are primarily limited by surface losses associated with TLSs in the 2.7 nm-thick native AlOx. Treatment with 49% HF removes surface AlOx completely; however, rapid oxide regrowth limits improvements in surface loss and long term device stability. Using these measurements we estimate that TLSs in aluminum interfaces contribute around 27% of the relaxation rate of state-of-the-art tantalum-on-silicon qubits that incorporate aluminum-based Josephson junctions.
format Preprint
id arxiv_https___arxiv_org_abs_2603_13183
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Quantifying surface losses in superconducting aluminum microwave resonators
Hedrick, Elizabeth
Bahrami, Faranak
Pakpour-Tabrizi, Alexander C.
Joshi, Atharv
Rahman, Q. Rumman
Yang, Ambrose
Chang, Ray D.
Bland, Matthew P.
Jindal, Apoorv
Cheng, Guangming
Yao, Nan
Cava, Robert J.
Houck, Andrew A.
de Leon, Nathalie P.
Quantum Physics
Materials Science
The recent realization of millisecond-scale coherence with tantalum-on-silicon transmon qubits showed that depositing the Al/AlOx/Al Josephson junction in a high purity, ultrahigh vacuum environment was critical for achieving lifetime-limited coherence, motivating careful examination of the aluminum surface two-level system (TLS) bath. Here, we measure the microwave absorption arising from surface TLSs in superconducting aluminum resonators, following methodology developed for tantalum resonators. We vary film and surface properties and correlate microwave measurements with materials characterization. We find that the lifetimes of superconducting aluminum resonators are primarily limited by surface losses associated with TLSs in the 2.7 nm-thick native AlOx. Treatment with 49% HF removes surface AlOx completely; however, rapid oxide regrowth limits improvements in surface loss and long term device stability. Using these measurements we estimate that TLSs in aluminum interfaces contribute around 27% of the relaxation rate of state-of-the-art tantalum-on-silicon qubits that incorporate aluminum-based Josephson junctions.
title Quantifying surface losses in superconducting aluminum microwave resonators
topic Quantum Physics
Materials Science
url https://arxiv.org/abs/2603.13183