Purification-based quantum error mitigation of pair-correlated electron simulations

Thomas E O’brien ,Brooks Foxen ,Hartmut Neven ,D Sank ,Aditya Locharla ,C Xing ,Dvir Kafri ,Jiang Zhang ,Andreas Bengtsson ,Jeremy Hilton ,Kannan Sankaragomathi ,M Ansmann ,Guifré Vidal ,Benjamin Villalonga ,Noah Shutty ,Reza Fatemi ,J Cogan ,Steven W Martin ,Bryan Woo ,Fedor Kostritsa ,Vladimir Shvarts ,Y Chen ,G Young ,D Gilboa ,W C Smith ,Joseph C Bardin ,Kunal Arya ,Orion Martin ,C Rocque ,Matthew P Harrigan ,Kevin C Miao ,Raja Gosula ,Catherine Vollgraff Heidweiller ,E Jeffrey ,Sean D Harrington ,P Heu ,Jindra Skruzny ,Alexander N Korotkov ,C Schuster ,Nicholas Zobrist ,R Potter ,I L Aleǐner ,Trevor Mccourt ,Leon Brill ,Nicholas Bushnell ,Alex Opremcak ,M Hansen ,R D Somma ,M R Hoffmann ,Marco Szalay ,Ashley Huff ,Dmitry A Abanin ,David Landhuis ,Oumarou Oumarou ,A Mieszala ,Aaron Shorter ,Brian Lester ,Ofer Naaman ,Z J Yao ,T White ,Roberto Collins ,Tanuj Khattar ,Murphy Yuezhen Niu ,Jarrod R Mcclean ,Edward Farhi ,Chris Quintana ,Doug Strain ,William J Huggins ,William Courtney ,Henry F Schurkus ,Sean Demura ,S Kim ,Juan Atalaya ,Alexandre Bourassa ,Justin Iveland ,S Polla ,David A Buell ,A L Crook ,Michael Broughton ,Trent Huang ,Ilya Drozdov ,Lily Laws ,M Kieferová ,Jiun How Ng ,Cody Jones ,Ryan Babbush ,Lara Faoro ,Murray Nguyen ,Charles Neill ,Alexis Morvan ,F D Malone ,W Liu ,L B Ioffe ,Ben Curtin ,Marissa Giustina ,William Giang ,K.-M Lau ,J Lee ,Bob B Buckley ,Catherine Erickson ,G Anselmetti ,Ningfeng Zhu ,Masoud Mohseni ,Rajeev Acharya ,K Lee ,Jenna Bovaird ,Leslie Flores Burgos ,P Yeh ,Juhwan Yoo ,Steve Habegger ,Anthony Nguyen ,Kevin J Satzinger ,J Kelly ,Mostafa Khezri ,A G Fowler ,Sergio Boixo ,J Campero ,Gina Bortoli ,A Nersisyan ,Tim Burger ,Erik Lucero ,P V Klimov ,P Roushan ,F Gkritsis ,S Mandrà ,M C Hamilton ,Vadim Smelyanskiy ,P Conner ,Adam Zalcman ,D Thor ,Abraham Asfaw ,Jonathan A Gross ,Alexander Lill ,Shirin Montazeri ,Kostyantyn Kechedzhi ,Matt Mcewen ,Dave Bacon ,Alfredo Torres ,Ebrahim Forati ,Frank Arute ,Michael Newman ,Z Chen ,A R Klots ,Pavol Juhás ,T I Andersen ,George Sterling ,Negar Saei ,A Petukhov ,Alejandro Grajales Dau ,William Livingston ,Pavel Laptev ,A Megrant ,Sabrina Hong ,R Movassagh ,S V Isakov ,V S Ferreira ,D M Debroy ,Leonid P Pryadko ,K R Anderson ,B Chiaro ,S Omonije ,Wojciech Mruczkiewicz ,Y Zhang ,Vincent E Elfving ,M J Shearn ,John Mark Kreikebaum ,Christian Gogolin ,Xiao Mi ,Craig Gidney ,A Dunsworth ,D Chik ,Brian Burkett ,M Neeley ,R M Allen ,Nicholas C Rubin

doi:10.1038/s41567-023-02240-y

Abstract

An important measure of the development of quantum computing platforms has been the simulation of increasingly complex physical systems. Before fault-tolerant quantum computing, robust error-mitigation strategies were necessary to continue this growth. Here, we validate recently introduced error-mitigation strategies that exploit the expectation that the ideal output of a quantum algorithm would be a pure state. We consider the task of simulating electron systems in the seniority-zero subspace where all electrons are paired with their opposite spin. This affords a computational stepping stone to a fully correlated model. We compare the performance of error mitigations on the basis of doubling quantum resources in time or in space on up to 20 qubits of a superconducting qubit quantum processor. We observe a reduction of error by one to two orders of magnitude below less sophisticated techniques such as postselection. We study how the gain from error mitigation scales with the system size and observe a polynomial suppression of error with increased resources. Extrapolation of our results indicates that substantial hardware improvements will be required for classically intractable variational chemistry simulations.

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