Superconducting quantum computing: a review

被引:0
|
作者
He-Liang Huang
Dachao Wu
Daojin Fan
Xiaobo Zhu
机构
[1] University of Science and Technology of China,Hefei National Laboratory for Physical Sciences at Microscale and Department of Modern Physics
[2] University of Science and Technology of China,Shanghai Branch, CAS Centre for Excellence and Synergetic Innovation Centre in Quantum Information and Quantum Physics
来源
Science China Information Sciences | 2020年 / 63卷
关键词
quantum computing; superconducting quantum computing; quantum bit; quantum algorithm; qubit design; qubit control; qubit readout;
D O I
暂无
中图分类号
学科分类号
摘要
Over the last two decades, tremendous advances have been made for constructing large-scale quantum computers. In particular, quantum computing platforms based on superconducting qubits have become the leading candidate for scalable quantum processor architecture, and the milestone of demonstrating quantum supremacy has been first achieved using 53 superconducting qubits in 2019. In this study, we provide a brief review on the experimental efforts towards the large-scale superconducting quantum computer, including qubit design, quantum control, readout techniques, and the implementations of error correction and quantum algorithms. Besides the state of the art, we finally discuss future perspectives, and which we hope will motivate further research.
引用
收藏
相关论文
共 50 条
  • [21] Digitized adiabatic quantum computing with a superconducting circuit
    R. Barends
    A. Shabani
    L. Lamata
    J. Kelly
    A. Mezzacapo
    U. Las Heras
    R. Babbush
    A. G. Fowler
    B. Campbell
    Yu Chen
    Z. Chen
    B. Chiaro
    A. Dunsworth
    E. Jeffrey
    E. Lucero
    A. Megrant
    J. Y. Mutus
    M. Neeley
    C. Neill
    P. J. J. O’Malley
    C. Quintana
    P. Roushan
    D. Sank
    A. Vainsencher
    J. Wenner
    T. C. White
    E. Solano
    H. Neven
    John M. Martinis
    Nature, 2016, 534 : 222 - 226
  • [22] Reworkable Superconducting Qubit Package for Quantum Computing
    Das, Rabindra N.
    Cummings, John
    Hazard, Thomas
    Rosenberg, Danna
    Conway, David
    Warnock, Shireen
    Gingras, Michael
    Huffman, Bethany
    Hirjibehedin, Cyrus F.
    Weber, Steven
    Yoder, Jonilyn
    Schwartz, Mollie
    PROCEEDINGS OF THE IEEE 74TH ELECTRONIC COMPONENTS AND TECHNOLOGY CONFERENCE, ECTC 2024, 2024, : 427 - 432
  • [23] Globally driven superconducting quantum computing architecture
    Menta, Roberto
    Cioni, Francesco
    Aiudi, Riccardo
    Polini, Marco
    Giovannetti, Vittorio
    PHYSICAL REVIEW RESEARCH, 2025, 7 (01):
  • [24] Digitized adiabatic quantum computing with a superconducting circuit
    Barends, R.
    Shabani, A.
    Lamata, L.
    Kelly, J.
    Mezzacapo, A.
    Heras, U. Las
    Babbush, R.
    Fowler, A. G.
    Campbell, B.
    Chen, Yu
    Chen, Z.
    Chiaro, B.
    Dunsworth, A.
    Jeffrey, E.
    Lucero, E.
    Megrant, A.
    Mutus, J. Y.
    Neeley, M.
    Neill, C.
    O'Malley, P. J. J.
    Quintana, C.
    Roushan, P.
    Sank, D.
    Vainsencher, A.
    Wenner, J.
    White, T. C.
    Solano, E.
    Neven, H.
    Martinis, John M.
    NATURE, 2016, 534 (7606) : 222 - 226
  • [25] Demonstration of quantum volume 64 on a superconducting quantum computing system
    Jurcevic, Petar
    Javadi-Abhari, Ali
    Bishop, Lev S.
    Lauer, Isaac
    Bogorin, Daniela F.
    Brink, Markus
    Capelluto, Lauren
    Gunluk, Oktay
    Itoko, Toshinari
    Kanazawa, Naoki
    Kandala, Abhinav
    Keefe, George A.
    Krsulich, Kevin
    Landers, William
    Lewandowski, Eric P.
    McClure, Douglas T.
    Nannicini, Giacomo
    Narasgond, Adinath
    Nayfeh, Hasan M.
    Pritchett, Emily
    Rothwell, Mary Beth
    Srinivasan, Srikanth
    Sundaresan, Neereja
    Wang, Cindy
    Wei, Ken X.
    Wood, Christopher J.
    Yau, Jeng-Bang
    Zhang, Eric J.
    Dial, Oliver E.
    Chow, Jerry M.
    Gambetta, Jay M.
    QUANTUM SCIENCE AND TECHNOLOGY, 2021, 6 (02)
  • [26] Gate-based superconducting quantum computing
    Kwon, Sangil
    Tomonaga, Akiyoshi
    Bhai, Gopika Lakshmi
    Devitt, Simon J.
    Tsai, Jaw-Shen
    JOURNAL OF APPLIED PHYSICS, 2021, 129 (04)
  • [27] Quantum Computing with Superconducting Circuits in the Picosecond Regime
    Zhu, Daoquan
    Jaako, Tuomas
    He, Qiongyi
    Rabl, Peter
    PHYSICAL REVIEW APPLIED, 2021, 16 (01)
  • [28] Quantum computing with superconducting quantum interference devices: a possible strategy
    Chiarello, F
    PHYSICS LETTERS A, 2000, 277 (4-5) : 189 - 193
  • [29] Demonstration of Adiabatic Variational Quantum Computing with a Superconducting Quantum Coprocessor
    Chen, Ming-Cheng
    Gong, Ming
    Xu, Xiaosi
    Yuan, Xiao
    Wang, Jian-Wen
    Wang, Can
    Ying, Chong
    Lin, Jin
    Xu, Yu
    Wu, Yulin
    Wang, Shiyu
    Deng, Hui
    Liang, Futian
    Peng, Cheng-Zhi
    Benjamin, Simon C.
    Zhu, Xiaobo
    Lu, Chao-Yang
    Pan, Jian-Wei
    PHYSICAL REVIEW LETTERS, 2020, 125 (18)
  • [30] Randomized Compiling for Scalable Quantum Computing on a Noisy Superconducting Quantum Processor
    Hashim, Akel
    Naik, Ravi K.
    Morvan, Alexis
    Ville, Jean-Loup
    Mitchell, Bradley
    Kreikebaum, John Mark
    Davis, Marc
    Smith, Ethan
    Iancu, Costin
    O'Brien, Kevin P.
    Hincks, Ian
    Wallman, Joel J.
    Emerson, Joseph
    Siddiqi, Irfan
    PHYSICAL REVIEW X, 2021, 11 (04)
12345