Growth and Structure of alpha-Ta films for Quantum Circuit Integration

Tantalum films incorporated into superconducting circuits have exhibited low surface losses, resulting in long-lived qubit states. Remaining loss pathways originate in microscopic defects which manifest as two level systems (TLS) at low temperature. These defects limit performance, so careful attention to tantalum film structures is critical for optimal use in quantum devices. In this work, we investigate the growth of tantalum using magnetron sputtering on sapphire, Si, and photoresist substrates. In the case of sapphire, we present procedures for growth of fully-oriented films with alpha-Ta [1 1 1] // Al2O3 [0 0 1] and alpha-Ta [1 -1 0] // Al2O3 [1 0 0] orientational relationships, and having residual resistivity ratios (RRR)   60 for 220 nm thick films. On Si, we find a complex grain texturing with Ta [1 1 0] normal to the substrate and RRR   30. We further demonstrate airbridge fabrication using Nb to nucleate alpha-Ta on photoresist surfaces. Superconducting resonators patterned from films on sapphire show TLS-limited quality factors of 1.4 +/- 0.3 x 10^6 at 10 mK. Structural characterization using scanning electron microscopy, X-ray diffraction, low temperature transport, secondary ion mass spectrometry, and transmission electron microscopy reveal the dependence of residual impurities and screw dislocation density on processing conditions. The results provide practical insights for fabrication of high-performing technological devices including qubit arrays, and guide future work on crystallographically deterministic qubit fabrication.