Beta Tantalum Transmon Qubits with Quality Factors Approaching 10 Million
Abstract
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 106, with the best qubit recording a time-averaged quality factor of (10.1 +/- 1.3) x 106. 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.
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