Implementation of quantum logic gates by nuclear magnetic resonance spectroscopy

被引:11
|
作者
Du, JF [1 ]
Wu, JH
Shi, MJ
Han, L
Zhou, XY
Ye, BJ
Weng, HM
Han, RD
机构
[1] Univ Sci & Technol China, Dept Modern Phys, Hefei 230027, Peoples R China
[2] Univ Sci & Technol China, Open Res Lab Quantum Commun & Quantum Computat, Hefei 230027, Peoples R China
[3] Univ Sci & Technol China, Struct Biol Lab, Hefei 230027, Peoples R China
[4] Chinese Acad Sci, Int Ctr Mat Phys, Shenyang 110015, Peoples R China
来源
CHINESE PHYSICS LETTERS | 2000年 / 17卷 / 01期
关键词
D O I
10.1088/0256-307X/17/1/022
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
Using nuclear magnetic resonance techniques with a solution of cytosine molecules, we show an implementation of certain quantum logic gates (including NOT gate, square-root of NOT gate and controlled-NOT gate), which have central importance in quantum computing. In addition, experimental results show that nuclear magnetic resonance spectroscopy can efficiently measure the result of quantum computing without attendant wave-functions collapse.
引用
收藏
页码:64 / 66
页数:3
相关论文
共 50 条
  • [41] Implementation of a multiple round quantum dense coding using nuclear magnetic resonance
    Zhang, JF
    Xie, JY
    Wang, CA
    Deng, ZW
    Lu, ZH
    Long, GL
    SCIENCE IN CHINA SERIES G-PHYSICS MECHANICS & ASTRONOMY, 2005, 48 (06): : 706 - 715
  • [42] Nuclear magnetic resonance implementation of universal quantum gate with constant Hamiltonian evolution
    Liu, Wenzhang
    Zhang, Jingfu
    Cao, Ye
    Huo, Wen Yi
    Hao, Liang
    Long, Gui Lu
    Deng, Zhiwei
    APPLIED PHYSICS LETTERS, 2009, 94 (06)
  • [43] Heteronuclear double resonance in nuclear magnetic resonance spectroscopy: Relaxation of multiple-quantum coherences
    Ulzega, Simone
    Verde, Mariachiara
    Ferrage, Fabien
    Bodenhausen, Geoffrey
    JOURNAL OF CHEMICAL PHYSICS, 2009, 131 (22):
  • [44] Implementation of Classical Logic Gates at Nano-Scale Level Using Magnetic Quantum Rings: A Theoretical Study
    Maiti, Santanu K.
    JOURNAL OF COMPUTATIONAL AND THEORETICAL NANOSCIENCE, 2011, 8 (04) : 676 - 693
  • [45] Covariance nuclear magnetic resonance spectroscopy
    Brüschweiler, R
    Zhang, FL
    JOURNAL OF CHEMICAL PHYSICS, 2004, 120 (11): : 5253 - 5260
  • [46] Microcoil nuclear magnetic resonance spectroscopy
    Webb, AG
    JOURNAL OF PHARMACEUTICAL AND BIOMEDICAL ANALYSIS, 2005, 38 (05) : 892 - 903
  • [47] NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY OF BICYCLOBUTANE
    WUTHRICH, K
    MEIBOOM, S
    SNYDER, LC
    JOURNAL OF CHEMICAL PHYSICS, 1970, 52 (01): : 230 - &
  • [48] Parallel nuclear magnetic resonance spectroscopy
    不详
    NATURE REVIEWS METHODS PRIMERS, 2021, 1 (01):
  • [49] Shiftless nuclear magnetic resonance spectroscopy
    Wu, Chin H.
    Opella, Stanley J.
    JOURNAL OF CHEMICAL PHYSICS, 2008, 128 (05):
  • [50] THE DIVERSITY OF NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY
    Liu, Corey W.
    Alekseyev, Viktor Y.
    Allwardt, Jeffrey R.
    Bankovich, Alexander J.
    Cade-Menun, Barbara J.
    Davis, Ronald W.
    Du, Lin-Shu
    Garcia, K. Christopher
    Herschlag, Daniel
    Khosla, Chaitan
    Kraut, Daniel A.
    Li, Qing
    Null, Brian
    Puglisi, Joseph D.
    Sigala, Paul A.
    Stebbins, Jonathan F.
    Varani, Luca
    BIOPHYSICS AND THE CHALLENGES OF EMERGING THREATS, 2009, : 65 - +
12345