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| Format: | Preprint |
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2026
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| Online-Zugang: | https://arxiv.org/abs/2603.13174 |
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| author | Joshi, Atharv Jindal, Apoorv Prestegaard, Paal H. Bahrami, Faranak Hedrick, Elizabeth Bland, Matthew P. Gerg, Tunmay Cheng, Guangming Yao, Nan Cava, Robert J. Houck, Andrew A. de Leon, Nathalie P. |
| author_facet | Joshi, Atharv Jindal, Apoorv Prestegaard, Paal H. Bahrami, Faranak Hedrick, Elizabeth Bland, Matthew P. Gerg, Tunmay Cheng, Guangming Yao, Nan Cava, Robert J. Houck, Andrew A. de Leon, Nathalie P. |
| contents | Tantalum-based transmon qubits are a promising platform for building large-scale quantum processors. So far, these qubits have been made from tantalum films grown exclusively in the alpha phase (α-Ta). The beta phase of tantalum (\{beta}-Ta) readily nucleates at room temperature, making it attractive for scalable qubit fabrication. However, \{beta}-Ta is widely believed to be detrimental to qubit performance because it has a lower superconducting critical temperature than α-Ta. We challenge this prevailing belief by fabricating low-loss transmon qubits from \{beta}-Ta films on sapphire. Across 11 qubits, the mean time-averaged quality factor is (5.6 +/- 2.3) x 10^6, with the best qubit recording a time-averaged quality factor of (10.1 +/- 1.3) x 10^6. Resonator studies demonstrate that the dominant microwave loss channel is surface two-level systems, with the surface loss contribution for \{beta}-Ta being about twice that of α-Ta. \{beta}-Ta films exhibit significant kinetic inductance, consistent with an estimated magnetic penetration depth of (1.78 +/- 0.02) μm. This work establishes \{beta}-Ta on sapphire as a material platform for realizing low-loss transmon qubits and other superconducting devices such as compact resonators, kinetic inductance detectors, and quasiparticle traps. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2603_13174 |
| institution | arXiv |
| publishDate | 2026 |
| record_format | arxiv |
| spellingShingle | Beta Tantalum Transmon Qubits with Quality Factors Approaching 10 Million Joshi, Atharv Jindal, Apoorv Prestegaard, Paal H. Bahrami, Faranak Hedrick, Elizabeth Bland, Matthew P. Gerg, Tunmay Cheng, Guangming Yao, Nan Cava, Robert J. Houck, Andrew A. de Leon, Nathalie P. Quantum Physics Materials Science Tantalum-based transmon qubits are a promising platform for building large-scale quantum processors. So far, these qubits have been made from tantalum films grown exclusively in the alpha phase (α-Ta). The beta phase of tantalum (\{beta}-Ta) readily nucleates at room temperature, making it attractive for scalable qubit fabrication. However, \{beta}-Ta is widely believed to be detrimental to qubit performance because it has a lower superconducting critical temperature than α-Ta. We challenge this prevailing belief by fabricating low-loss transmon qubits from \{beta}-Ta films on sapphire. Across 11 qubits, the mean time-averaged quality factor is (5.6 +/- 2.3) x 10^6, with the best qubit recording a time-averaged quality factor of (10.1 +/- 1.3) x 10^6. Resonator studies demonstrate that the dominant microwave loss channel is surface two-level systems, with the surface loss contribution for \{beta}-Ta being about twice that of α-Ta. \{beta}-Ta films exhibit significant kinetic inductance, consistent with an estimated magnetic penetration depth of (1.78 +/- 0.02) μm. This work establishes \{beta}-Ta on sapphire as a material platform for realizing low-loss transmon qubits and other superconducting devices such as compact resonators, kinetic inductance detectors, and quasiparticle traps. |
| title | Beta Tantalum Transmon Qubits with Quality Factors Approaching 10 Million |
| topic | Quantum Physics Materials Science |
| url | https://arxiv.org/abs/2603.13174 |