Related papers: Reversing Hydrogen-Related Loss in $α$-Ta Thin Films for Quantum Device Fabrication

Reversing Hydrogen-Related Loss in $α$-Ta Thin Films for Quantum Device Fabrication

URL: http://arxiv.org/abs/2503.12889v1
Date: Mon, 17 Mar 2025 07:33:49 GMT
Title: Reversing Hydrogen-Related Loss in $α$-Ta Thin Films for Quantum Device Fabrication
Authors: D. P. Lozano, M. Mongillo, B. Raes, Y. Canvel, S. Massar, A. M. Vadiraj, Ts. Ivanov, R. Acharya, J. Van Damme, J. Van de Vondel, D. Wan, A. Potocnik, K. De Greve,
Abstract summary: Hydrogen absorption during fabrication, particularly when removing the native oxide, can degrade performance by increasing microwave loss.<n>In this work, we demonstrate that hydrogen can enter $alpha$-Ta thin films when exposed to 10 vol% hydrofluoric acid for 3 minutes or longer.<n> reduced resonator performance is likely caused by the formation of non-superconducting tantalum hydride precipitates.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: $\alpha$-Tantalum ($\alpha$-Ta) is an emerging material for superconducting qubit fabrication due to the low microwave loss of its stable native oxide. However, hydrogen absorption during fabrication, particularly when removing the native oxide, can degrade performance by increasing microwave loss. In this work, we demonstrate that hydrogen can enter $\alpha$-Ta thin films when exposed to 10 vol% hydrofluoric acid for 3 minutes or longer, leading to an increase in power-independent ohmic loss in high-Q resonators at millikelvin temperatures. Reduced resonator performance is likely caused by the formation of non-superconducting tantalum hydride (TaH$_x$) precipitates. We further show that annealing at 500{\deg}C in ultra-high vacuum (10$^{-8}$ Torr) for one hour fully removes hydrogen and restores the resonators' intrinsic quality factors to ~4 million at the single-photon level. These findings identify a previously unreported loss mechanism in $\alpha$-Ta and offer a pathway to reverse hydrogen-induced degradation in quantum devices based on Ta and, by extension also Nb, enabling more robust fabrication processes for superconducting qubits.

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