Phase transition in Random Circuit Sampling

A. Morvan,B. Villalonga,X. Mi,S. Mandrà,A. Bengtsson,P. V. Klimov, Z. Chen,S. Hong, C. Erickson,I. K. Drozdov, J. Chau, G. Laun,R. Movassagh,A. Asfaw, L. T. A. N. Brandão, R. Peralta,D. Abanin, R. Acharya,R. Allen, T. I. Andersen,K. Anderson, M. Ansmann, F. Arute,K. Arya,J. Atalaya,J. C. Bardin,A. Bilmes, G. Bortoli,A. Bourassa, J. Bovaird, L. Brill, M. Broughton,B. B. Buckley, D. A. Buell, T. Burger, B. Burkett, N. Bushnell, J. Campero, H. S. Chang, B. Chiaro, D. Chik, C. Chou, J. Cogan, R. Collins, P. Conner,W. Courtney, A. L. Crook,B. Curtin,D. M. Debroy,A. Del Toro Barba, S. Demura,A. Di Paolo,A. Dunsworth,L. Faoro,E. Farhi,R. Fatemi,V. S. Ferreira, L. Flores Burgos,E. Forati,A. G. Fowler,B. Foxen, G. Garcia,E. Genois, W. Giang,C. Gidney,D. Gilboa,M. Giustina, R. Gosula,A. Grajales Dau, J. A. Gross, S. Habegger,M. C. Hamilton, M. Hansen,M. P. Harrigan, S. D. Harrington, P. Heu, M. R. Hoffmann, T. Huang, A. Huff,W. J. Huggins,L. B. Ioffe,S. V. Isakov, J. Iveland, E. Jeffrey, Z. Jiang,C. Jones,P. Juhas, D. Kafri,T. Khattar, M. Khezri,M. Kieferová, S. Kim,A. Kitaev,A. R. Klots,A. N. Korotkov, F. Kostritsa, J. M. Kreikebaum, D. Landhuis, P. Laptev, K. -M. Lau, L. Laws,J. Lee, K. W. Lee,Y. D. Lensky, B. J. Lester,A. T. Lill, W. Liu,A. Locharla,F. D. Malone,O. Martin, S. Martin,J. R. McClean,M. McEwen,K. C. Miao, A. Mieszala,S. Montazeri, W. Mruczkiewicz,O. Naaman,M. Neeley,C. Neill, A. Nersisyan,M. Newman, J. H. Ng, A. Nguyen, M. Nguyen,M. Yuezhen Niu, T. E. O'Brien, S. Omonije,A. Opremcak, A. Petukhov, R. Potter,L. P. Pryadko,C. Quintana, D. M. Rhodes, C. Rocque, P. Roushan,N. C. Rubin,N. Saei,D. Sank,K. Sankaragomathi,K. J. Satzinger, H. F. Schurkus, C. Schuster, M. J. Shearn, A. Shorter,N. Shutty, V. Shvarts, V. Sivak, J. Skruzny,W. C. Smith,R. D. Somma,G. Sterling, D. Strain,M. Szalay, D. Thor, A. Torres,G. Vidal,C. Vollgraff Heidweiller,T. White,B. W. K. Woo, C. Xing, Z. J. Yao, P. Yeh, J. Yoo, G. Young,A. Zalcman, Y. Zhang,N. Zhu,N. Zobrist,E. G. Rieffel,R. Biswas,R. Babbush,D. Bacon,J. Hilton,E. Lucero,H. Neven, A. Megrant,J. Kelly, I. Aleiner,V. Smelyanskiy,K. Kechedzhi, Y. Chen,S. Boixo

arXiv (Cornell University)（2023）

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摘要

Quantum computers hold the promise of executing tasks beyond the capability of classical computers. Noise competes with coherent evolution and destroys long-range correlations, making it an outstanding challenge to fully leverage the computation power of near-term quantum processors. We report Random Circuit Sampling (RCS) experiments where we identify distinct phases driven by the interplay between quantum dynamics and noise. Using cross-entropy benchmarking, we observe phase boundaries which can define the computational complexity of noisy quantum evolution. We conclude by presenting an RCS experiment with 70 qubits at 24 cycles. We estimate the computational cost against improved classical methods and demonstrate that our experiment is beyond the capabilities of existing classical supercomputers.

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关键词

sampling,phase,transition

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