Phase transition in Random Circuit Sampling

A. Morvan; B. Villalonga; X. Mi; S. Mandr\`a; 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. Brand\~ao; 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. Kieferov\'a; 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; W. P. Livingston; 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; E. Rosenberg; 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:2304.11119·quant-ph·November 7, 2024·38 cites

Phase transition in Random Circuit Sampling

A. Morvan, B. Villalonga, X. Mi, S. Mandr\`a, 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. Brand\~ao, R. Peralta, D. Abanin, R. Acharya,, R. Allen, T. I. Andersen, K. Anderson, M. Ansmann

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TL;DR

This paper demonstrates experimentally and theoretically that Random Circuit Sampling exhibits two phase transitions influenced by noise and circuit depth, revealing a stable complex phase that current quantum processors can access.

Contribution

It introduces a statistical model explaining two phase transitions in RCS and experimentally observes these transitions with 67 qubits, surpassing classical computational capabilities.

Findings

01

Identification of a dynamical phase transition related to circuit depth.

02

Observation of a quantum phase transition controlled by noise levels.

03

Demonstration of quantum advantage with 67 qubits beyond classical simulation.

Abstract

Undesired coupling to the surrounding environment destroys long-range correlations on quantum processors and hinders the coherent evolution in the nominally available computational space. This incoherent noise is an outstanding challenge to fully leverage the computation power of near-term quantum processors. It has been shown that benchmarking Random Circuit Sampling (RCS) with Cross-Entropy Benchmarking (XEB) can provide a reliable estimate of the effective size of the Hilbert space coherently available. The extent to which the presence of noise can trivialize the outputs of a given quantum algorithm, i.e. making it spoofable by a classical computation, is an unanswered question. Here, by implementing an RCS algorithm we demonstrate experimentally that there are two phase transitions observable with XEB, which we explain theoretically with a statistical model. The first is a dynamical…

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Taxonomy

TopicsNeural Networks and Applications · Theoretical and Computational Physics · Quantum many-body systems