Second-order decoherence mechanisms of a transmon qubit probed with thermal microwave states

J. Goetz, F. Deppe, P. Eder, M. Fischer, M. Müting, J. Puertas Martínez, S. Pogorzalek, F. Wulschner, E. Xie, K. G. Fedorov, A. Marx, R. Gross

Research output: Contribution to journalArticlepeer-review

14 Scopus citations

Abstract

Thermal microwave states are omnipresent noise sources in superconducting quantum circuits covering all relevant frequency regimes. We use them as a probe to identify three second-order decoherence mechanisms of a superconducting transmon qubit. First, we quantify the efficiency of a resonator filter in the dispersive Jaynes-Cummings regime and find evidence for parasitic loss channels. Second, we probe second-order noise in the low-frequency regime and demonstrate the expected T 3 temperature dependence of the qubit dephasing rate. Finally, we show that qubit parameter fluctuations due to two-level states are enhanced under the influence of thermal microwave states. In particular, we experimentally confirm the T 2 -dependence of the fluctuation spectrum expected for noninteracting two-level states.

Original languageEnglish
Article number025002
JournalQuantum Science and Technology
Volume2
Issue number2
DOIs
StatePublished - 1 Jun 2017

Keywords

  • correlation measurements
  • fluctuations
  • microwave technology
  • quantum coherence
  • quantum information
  • superconducting qubits
  • thermal noise

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