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Saving superconducting quantum processors from decay and correlated errors generated by gamma and cosmic rays

John M. Martinis

2021npj Quantum Information137 citationsDOIOpen Access PDF

Abstract

Abstract Error-corrected quantum computers can only work if errors are small and uncorrelated. Here, I show how cosmic rays or stray background radiation affects superconducting qubits by modeling the phonon to electron/quasiparticle down-conversion physics. For present designs, the model predicts about 57% of the radiation energy breaks Cooper pairs into quasiparticles, which then vigorously suppress the qubit energy relaxation time ( T 1 ~ 600 ns) over a large area (cm) and for a long time (ms). Such large and correlated decay kills error correction. Using this quantitative model, I show how this energy can be channeled away from the qubit so that this error mechanism can be reduced by many orders of magnitude. I also comment on how this affects other solid-state qubits.

Topics & Concepts

QubitPhysicsQuasiparticleSuperconductivityQuantum mechanicsCooper pairPhase qubitQuantum error correctionQuantumQuantum computerQuantum and electron transport phenomenaQuantum Computing Algorithms and ArchitectureQuantum Information and Cryptography
Saving superconducting quantum processors from decay and correlated errors generated by gamma and cosmic rays | Litcius