Demonstration of Quantum Zeno Effect in a Superconducting Phase Qubit

被引:7
作者
Zhang, Z. -T. [1 ,2 ]
Xue, Z. -Y. [1 ]
机构
[1] S China Normal Univ, Lab Quantum Informat Technol, Sch Phys & Telecommun Engn, Guangzhou 510006, Guangdong, Peoples R China
[2] Nanjing Univ, Natl Lab Solid State Microstruct, Sch Phys, Nanjing 210093, Peoples R China
来源
JETP LETTERS | 2011年 / 93卷 / 06期
关键词
COMPUTATION;
D O I
10.1134/S0021364011060130
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
Quantum Zeno effect is a significant tool in quantum manipulating and computing. We propose its observation in superconducting phase qubit with two experimentally feasible measurement schemes. The conventional measurement method is used to achieve the proposed pulse and continuous readout of the qubit state, which are analyzed by projection assumption and Monte Carlo wavefunction simulation, respectively. Our scheme gives a direct implementation of quantum Zeno effect in a superconducting phase qubit.
引用
收藏
页码:349 / 353
页数:5
相关论文
共 50 条
[41]   Quantum control of an oscillator with a Kerr-cat qubit [J].
Ding, Andy Z. ;
Brock, Benjamin L. ;
Eickbusch, Alec ;
Koottandavida, Akshay ;
Frattini, Nicholas E. ;
Cortinas, Rodrigo G. ;
Joshi, Vidul R. ;
de Graaf, Stijn J. ;
Chapman, Benjamin J. ;
Ganjam, Suhas ;
Frunzio, Luigi ;
Schoelkopf, Robert J. ;
Devoret, Michel H. .
NATURE COMMUNICATIONS, 2025, 16 (01)
[42]   A programmable two-qubit quantum processor in silicon [J].
Watson, T. F. ;
Philips, S. G. J. ;
Kawakami, E. ;
Ward, D. R. ;
Scarlino, P. ;
Veldhorst, M. ;
Savage, D. E. ;
Lagally, M. G. ;
Friesen, Mark ;
Coppersmith, S. N. ;
Eriksson, M. A. ;
Vandersypen, L. M. K. .
NATURE, 2018, 555 (7698) :633-+
[43]   ENTANGLEMENT CREATION IN SEMICONDUCTOR QUANTUM DOT CHARGE QUBIT [J].
Buscemi, Fabrizio ;
Bordone, Paolo ;
Bertoni, Andrea .
INTERNATIONAL JOURNAL OF QUANTUM INFORMATION, 2011, 9 :111-118
[44]   Readout and dynamics of a qubit built on three quantum dots [J].
Luczak, Jakub ;
Bulka, Bogdan R. .
PHYSICAL REVIEW B, 2014, 90 (16)
[45]   Quantum-Dot-Based Resonant Exchange Qubit [J].
Medford, J. ;
Beil, J. ;
Taylor, J. M. ;
Rashba, E. I. ;
Lu, H. ;
Gossard, A. C. ;
Marcus, C. M. .
PHYSICAL REVIEW LETTERS, 2013, 111 (05)
[46]   Logical Qubit in a Linear Array of Semiconductor Quantum Dots [J].
Jones, Cody ;
Fogarty, Michael A. ;
Morello, Andrea ;
Gyure, Mark F. ;
Dzurak, Andrew S. ;
Ladd, Thaddeus D. .
PHYSICAL REVIEW X, 2018, 8 (02)
[47]   Emulating Quantum Teleportation of a Majorana Zero Mode Qubit [J].
Huang, He-Liang ;
Narozniake, Marek ;
Liang, Futian ;
Zhao, Youwei ;
Castellano, Anthony D. ;
Gong, Ming ;
Wu, Yulin ;
Wang, Shiyu ;
Lin, Jin ;
Xu, Yu ;
Deng, Hui ;
Rong, Hao ;
Dowling, Jonathan P. ;
Peng, Cheng-Zhi ;
Byrnes, Tim ;
Zhu, Xiaobo ;
Pan, Jian-Wei .
PHYSICAL REVIEW LETTERS, 2021, 126 (09)
[48]   Algebraic representation of Three Qubit Quantum Circuit Problems [J].
Chew, K. Y. ;
Shah, N. M. ;
Chan, K. T. .
MALAYSIAN JOURNAL OF MATHEMATICAL SCIENCES, 2022, 16 (03) :559-582
[49]   The Triangular and Coulomb Bound Potential Quantum Dot Qubit [J].
Li, Hong-juan ;
Yin, Ji-wen ;
Xiao, Jing-lin .
JOURNAL OF LOW TEMPERATURE PHYSICS, 2013, 172 (3-4) :266-273
[50]   Black hole qubit correspondence from quantum circuits [J].
Prudencio, Thiago ;
Cirilo-Lombardo, Diego Julio ;
Silva, Edilberto O. ;
Belich, Humberto .
MODERN PHYSICS LETTERS A, 2015, 30 (23)
12345