Kevin Schultz

On-Demand Correlated Errors in Superconducting Qubits from a Particle Accelerator

  1. Thomas McJunkin,
  2. A.W. Hunt,
  3. Yenuel Jones-Alberty,
  4. T.M. Haard,
  5. M.K. Spear,
  6. James Shackford,
  7. Tom Gilliss,
  8. Mayra Amezcua,
  9. C. A. Watson,
  10. T.M. Sweeney,
  11. J.A. Hoffmann,
  12. and Kevin Schultz
Ionizing radiation is a known source of correlated errors in superconducting quantum processors, inhibiting the functionality of quantum error correction surface codes. High-energy
photons and charged particles deposit pair-breaking energy into these systems leading to excess quasiparticles near Josephson junctions that increase qubit decoherence. Previous investigations of this problem have relied on ambient, stochastic sources of ionizing radiation or alternative methods of quasiparticle generation. Here, we present a facility that couples an electron linear accelerator (linac) to a dilution refrigerator to study ionizing radiation in quantum systems. A single linac electron closely mimics the energy deposition characteristics of a typical cosmic-ray muon, and we demonstrate the facility’s usefulness with a multi-qubit superconducting transmon chip. Characteristic radiation-induced relaxation errors are quickly and easily collected with the speed and timing information of the linac. Additionally, we present qubit excitation and detuning errors that can be difficult to detect without the on-demand source of ionizing radiation. These error signatures are shown to be dependent on the junction placement and surrounding superconducting gaps.
arxiv pdf

Characterization of Radiation-Induced Errors in Superconducting Qubits Protected with Various Gap-Engineering Strategies

  1. H. Douglas Pinckney,
  2. Thomas McJunkin,
  3. Alan W. Hunt,
  4. Patrick M. Harrington,
  5. Hannah P. Binney,
  6. Max Hays,
  7. Yenuel Jones-Alberty,
  8. Kate Azar,
  9. Felipe Contipelli,
  10. Renée DePencier Piñero,
  11. Jeffrey M. Gertler,
  12. Michael Gingras,
  13. Aranya Goswami,
  14. Cyrus F. Hirjibehedin,
  15. Mingyu Li,
  16. Mathis Moes,
  17. Bethany M. Niedzielski,
  18. Mallika T. Randeria,
  19. Ryan Sitler,
  20. Matthew K. Spear,
  21. Hannah Stickler,
  22. Jiatong Yang,
  23. Wouter Van De Pontseele,
  24. Mollie E. Schwartz,
  25. Jeffrey A. Grover,
  26. Kevin Schultz,
  27. Kyle Serniak,
  28. Joseph A. Formaggio,
  29. and William D. Oliver
Impacts from high-energy particles cause correlated errors in superconducting qubits by increasing the quasiparticle density in the vicinity of the Josephson junctions (JJs). Such errors
are particularly harmful as they cannot be easily remedied via conventional error correcting codes. Recent experiments reduced correlated errors by making the difference in superconducting gap energy across the JJ larger than the qubit energy. In this work, we assess gap engineering near the JJ (δΔJJ) and the capacitor/ground-plane (δΔM1) by exposing arrays of transmon qubits to two sources of radiation. For α-particles from an 241Am source, we observe T1 errors correlated in space and time, supporting a hypothesis that hadronic cosmic rays are a major contributor to the 10−10 error floor observed in Ref. 1. For electrons from a pulsed linear accelerator, we observe temporally correlated T1 and T2 errors, this measurement is insensitive to spatial correlations. We observe that the severity of correlated T1 errors is reduced for qubit arrays with a greater degree of gap engineering at the JJ. For both T1 and T2 errors, the recovery time is hastened by an increased δΔM1, which we attribute to the trapping of quasiparticles into the capacitor/ground-plane. We construct a model of quasiparticle dynamics that qualitatively agrees with our observations. This work reinforces the multifaceted influence of radiation on superconducting qubits and provides strategies for improving radiation resilience.
arxiv pdf