TOF-SIMS Analysis of Decoherence Sources in Nb Superconducting
Resonators
- URL: http://arxiv.org/abs/2108.13539v1
- Date: Mon, 30 Aug 2021 22:22:47 GMT
- Title: TOF-SIMS Analysis of Decoherence Sources in Nb Superconducting
Resonators
- Authors: Akshay A. Murthy, Jae-Yel Lee, Cameron Kopas, Matthew J. Reagor,
Anthony P. McFadden, David P. Pappas, Mattia Checchin, Anna Grassellino,
Alexander Romanenko
- Abstract summary: Superconducting qubits have emerged as a potentially foundational platform technology.
Material quality and interfacial structures continue to curb device performance.
Two-level system defects in the thin film and adjacent regions introduce noise and dissipate electromagnetic energy.
- Score: 48.7576911714538
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Superconducting qubits have emerged as a potentially foundational platform
technology for addressing complex computational problems deemed intractable
with classical computing. Despite recent advances enabling multiqubit designs
that exhibit coherence lifetimes on the order of hundreds of $\mu$s, material
quality and interfacial structures continue to curb device performance. When
niobium is deployed as the superconducting material, two-level system defects
in the thin film and adjacent dielectric regions introduce stochastic noise and
dissipate electromagnetic energy at the cryogenic operating temperatures. In
this study, we utilize time-of-flight secondary ion mass spectrometry
(TOF-SIMS) to understand the role specific fabrication procedures play in
introducing such dissipation mechanisms in these complex systems. We
interrogated Nb thin films and transmon qubit structures fabricated by Rigetti
Computing and at the National Institute of Standards and Technology through
slight variations in the processing and vacuum conditions. We find that when Nb
film is sputtered onto the Si substrate, oxide and silicide regions are
generated at various interfaces. We also observe that impurity species such as
niobium hydrides and carbides are incorporated within the niobium layer during
the subsequent lithographic patterning steps. The formation of these resistive
compounds likely impact the superconducting properties of the Nb thin film.
Additionally, we observe the presence of halogen species distributed throughout
the patterned thin films. We conclude by hypothesizing the source of such
impurities in these structures in an effort to intelligently fabricate
superconducting qubits and extend coherence times moving forward.
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