Authors
Matt McEwen, Lara Faoro, Kunal Arya, Andrew Dunsworth, Trent Huang, Seon Kim, Brian Burkett, Austin Fowler, Frank Arute, Joseph C Bardin, Andreas Bengtsson, Alexander Bilmes, Bob B Buckley, Nicholas Bushnell, Zijun Chen, Roberto Collins, Sean Demura, Alan R Derk, Catherine Erickson, Marissa Giustina, Sean D Harrington, Sabrina Hong, Evan Jeffrey, Julian Kelly, Paul V Klimov, Fedor Kostritsa, Pavel Laptev, Aditya Locharla, Xiao Mi, Kevin C Miao, Shirin Montazeri, Josh Mutus, Ofer Naaman, Matthew Neeley, Charles Neill, Alex Opremcak, Chris Quintana, Nicholas Redd, Pedram Roushan, Daniel Sank, Kevin J Satzinger, Vladimir Shvarts, Theodore White, Z Jamie Yao, Ping Yeh, Juhwan Yoo, Yu Chen, Vadim Smelyanskiy, John M Martinis, Hartmut Neven, Anthony Megrant, Lev Ioffe, Rami Barends
Publication date
2022/1
Journal
Nature Physics
Volume
18
Issue
1
Pages
107-111
Publisher
Nature Publishing Group UK
Description
Scalable quantum computing can become a reality with error correction, provided that coherent qubits can be constructed in large arrays,. The key premise is that physical errors can remain both small and sufficiently uncorrelated as devices scale, so that logical error rates can be exponentially suppressed. However, impacts from cosmic rays and latent radioactivity violate these assumptions. An impinging particle can ionize the substrate and induce a burst of quasiparticles that destroys qubit coherence throughout the device. High-energy radiation has been identified as a source of error in pilot superconducting quantum devices, –, but the effect on large-scale algorithms and error correction remains an open question. Elucidating the physics involved requires operating large numbers of qubits at the same rapid timescales necessary for error correction. Here, we use space- and time-resolved measurements of a …
Total citations
Scholar articles
M McEwen, L Faoro, K Arya, A Dunsworth, T Huang… - Nature Physics, 2022
