Formation of robust bound states of interacting microwave photons

Alexis Morvan; Trond I. Andersen; Xiao Mi; Charles Neill; Andre; Petukhov; Kostyantyn Kechedzhi; Dmitry Abanin; Rajeev Acharya; Frank Arute,; Kunal Arya; Abraham Asfaw; Juan Atalaya; Ryan Babbush; Dave Bacon; Joseph C.; Bardin; Joao Basso; Andreas Bengtsson; Gina Bortoli; Alexandre Bourassa,; Jenna Bovaird; Leon Brill; Michael Broughton; Bob B. Buckley; David A. Buell,; Tim Burger; Brian Burkett; Nicholas Bushnell; Zijun Chen; Ben Chiaro; Roberto; Collins; Paul Conner; William Courtney; Alexander L. Crook; Ben Curtin,; Dripto M. Debroy; Alexander Del Toro Barba; Sean Demura; Andrew Dunsworth,; Daniel Eppens; Catherine Erickson; Lara Faoro; Edward Farhi; Reza Fatemi,; Leslie Flores Burgos; Ebrahim Forati; Austin G. Fowler; Brooks Foxen; William; Giang; Craig Gidney; Dar Gilboa; Marissa Giustina; Alejandro Grajales Dau,; Jonathan A. Gross; Steve Habegger; Michael C. Hamilton; Matthew P. Harrigan,; Sean D. Harrington; Jeremy Hilton; Markus Hoffmann; Sabrina Hong; Trent; Huang; Ashley Huff; William J. Huggins; Sergei V. Isakov; Justin Iveland,; Evan Jeffrey; Zhang Jiang; Cody Jones; Pavol Juhas; Dvir Kafri; Tanuj; Khattar; Mostafa Khezri; Marika Kieferova; Seon Kim; Alexei Kitaev; Paul V.; Klimov; Andrey R. Klots; Alexander N. Korotkov; Fedor Kostritsa; John Mark; Kreikebaum; David Landhuis; Pavel Laptev; Kim-Ming Lau; Lily Laws; Joonho; Lee; Kenny Lee; Brian J. Lester; Alexander Lill; Wayne Liu; Aditya Locharla,; Erik Lucero; Fionn D. Malone; Orion Martin; Jarrod R. McClean; Matt McEwen,; Bernardo Meurer Costa; Kevin C. Miao; Masoud Mohseni; Shirin Montazeri; Emily; Mount; Wojciech Mruczkiewicz; Ofer Naaman; Matthew Neeley; Ani Nersisyan,; Michael Newman; Anthony Nguyen; Murray Nguyen; Murphy Yuezhen Niu; Thomas E.; O'Brien; Ricardo Olenewa; Alex Opremcak; Rebecca Potter; Chris Quintana,; Nicholas C. Rubin; Negar Saei; Daniel Sank; Kannan Sankaragomathi; Kevin J.; Satzinger; Henry F. Schurkus; Christopher Schuster; Michael J. Shearn; Aaron; Shorter; Vladimir Shvarts; Jindra Skruzny; W. Clarke Smith; George Sterling,; Doug Strain; Yuan Su; Marco Szalay; Alfredo Torres; Guifre Vidal; Benjamin; Villalonga; Catherine Vollgraff Heidweiller; Theodore White; Cheng Xing; Z.; Jamie Yao; Ping Yeh; Juhwan Yoo; Adam Zalcman; Yaxing Zhang; Ningfeng Zhu,; Hartmut Neven; Sergio Boixo; Anthony Megrant; Julian Kelly; Yu Chen; Vadim; Smelyanskiy; Igor Aleiner; Lev B. Ioffe; Pedram Roushan

arXiv:2206.05254·quant-ph·December 23, 2022

Formation of robust bound states of interacting microwave photons

Alexis Morvan, Trond I. Andersen, Xiao Mi, Charles Neill, Andre, Petukhov, Kostyantyn Kechedzhi, Dmitry Abanin, Rajeev Acharya, Frank Arute,, Kunal Arya, Abraham Asfaw, Juan Atalaya, Ryan Babbush, Dave Bacon, Joseph C., Bardin, Joao Basso, Andreas Bengtsson, Gina Bortoli

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TL;DR

This paper demonstrates the formation and stability of multi-photon bound states in a superconducting qubit ring, revealing their resilience beyond integrability, with implications for understanding strongly correlated quantum systems.

Contribution

It provides the first experimental observation of stable multi-photon bound states in a superconducting circuit, even when integrability is broken.

Findings

01

Bound states observed for up to 5 photons

02

Bound states remain stable beyond integrability

03

Developed phase-sensitive spectrum construction method

Abstract

Systems of correlated particles appear in many fields of science and represent some of the most intractable puzzles in nature. The computational challenge in these systems arises when interactions become comparable to other energy scales, which makes the state of each particle depend on all other particles. The lack of general solutions for the 3-body problem and acceptable theory for strongly correlated electrons shows that our understanding of correlated systems fades when the particle number or the interaction strength increases. One of the hallmarks of interacting systems is the formation of multi-particle bound states. In a ring of 24 superconducting qubits, we develop a high fidelity parameterizable fSim gate that we use to implement the periodic quantum circuit of the spin-1/2 XXZ model, an archetypal model of interaction. By placing microwave photons in adjacent qubit sites, we…

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