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    于长水

    • 教授     博士生导师   硕士生导师
    • 主要任职:物理学院党委书记
    • 其他任职:无
    • 性别:男
    • 毕业院校:大连理工大学
    • 学位:博士
    • 所在单位:物理学院
    • 学科:理论物理
    • 办公地点:313

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    研究领域

    115) Yang Zhang, Yu-bo Ma, Yu Guo*,  Chang-shui Yu*

       Perfect photon absorption based on the optical parametric process 

       Chin. Phys. B  

    114) Li-qiang Zhang, Chang-shui Yu

       The optimal approximation of qubit states with limited quantum states

      Phys. Letts. A. 398, 127286 (2021).

    113) Li-qiang Zhang, Chang-shui Yu

       The best approximation of a given qubit state with the limited pure-state set

       Journal Physics A. 54, 085205 (2021).

    112) Amjad Sohail, Rizwan Ahmed,  Chang shui Yu

       Switchable and Enhanced Absorption via Qubit-Mechanical Nonlinear Interaction in a Hybrid Optomechanical System

       Int J Theor Phys https://doi.org/10.1007/s10773-020-04655-2

    111) Jin-na Fan, Shao-xiong Wu*, Chang-shui Yu*

    Quantum acceleration by an ancillary system in non-Markovian environments

    Quant. Inf. Proc. 20, 9 (2021).

    110) Deng-hui Yu,  Chang-shui Yu*

    Quantifying entanglement in terms of an operational way

    Chin. Phys. B  30, 020302 (2021).

    109) Amjad Sohail, M. Rana, S. Ikram, T. Munir,  T. Hussain, R. Ahmed, Chang-shui Yu,

    Enhancement of mechanical entanglement in hybrid optomechanical system

    Quant. Inf. Proc. 19, 372 (2020).

    108) Deng-hui Yu, Yu-qiang Liu, Chang-shui Yu*

    Quantifying coherence in terms of the pure-state coherence

    Phys. Rev. A  101, 062114 (2020).

    107) Shao-xiong Wu*, Chang-shui Yu*,

        Margolus-Levitin speed limit across quantum to classical regimes based on trace distance

     Chinese Physics B  20, 050302 (2020).

    106) Shao-xiong Wu*, Chang-shui Yu*,

    Quantum speed limit based on the bound of Bures angle.

    Scientific Reports 10, 5500 (2020).

    105) Nan-nan Zhou, Bao-qing Guo, Chang-shui Yu*

        Quantum versus classical: extremal photon statistics signal the extremal entanglement.

         Journal Physics B 53, 155501 (2020).

    104) Amjad Sohail, Rizwan Ahmed, Chang-shui Yu*, and Tariq Munir, Fakhar Alam

     Tunable optical response of an optomechanical system with two mechanically driven resonators.

        Physica Scripta 95, 045105(2020).

    103) Amjad Sohail, Rizwan Ahmed, Chang-shui Yu, and Tariq Munir, 

        Enhanced entanglement induced by Coulomb interaction in coupled optomechanical systems.

        Physica Scripta 95, 035108(2020).

    102) Ting-ting Shao, Dong-mo Li, Chang-shui Yu*

        The bound of quantum Fisher information induced by the superposition input states.

       Quant. Inf. Proc. 19, 11(2020).

    101) Deng-hui Yu, Yu-qiang Liu, Chang-shui Yu*

    Effects of the Coherence on the Parameter Estimation in a Quantum Metrology Scheme with  Driving Fields.   

    IJTP 59, 993 (2020)

    100) Tong Liu, Yang Zhang, Bao-qing Guo,  Chang-shui Yu, Wei-ning Zhang

       Creation of superposition of arbitrary states encoded in two three-dimensional cavities

       Opt. Exp. 27, 027168(2019).

    99) Chang-shui Yu, Dong-mo Li, Nan-nan Zhou

        Monogamy of finite dimensional entanglement induced by coherence. 

        Europhys. Lett. 125, 50001(2019)

    98) Bao-qing Guo, Tong Liu, Chang-shui Yu

        Multifunctional quantum thermal device utilizing three qubits 

     Phys. Rev. E  99,  032112 (2019)

    97) Chang-shui Yu, Bao-qing Guo, Tong Liu

         Quantum self-contained refrigerator in terms of the cavity quantum electrodynamics

        Opt. Exp. 27, 4498 (2019).

    96) Li-qiang Zhang,  Si-ren Yang, Chang-shui Yu

       Analytically computable of the symmetric quantum correlation.

      Annale der Physik 531,  1800178 (2019).

    95) Jun Zhang,Yan Han, and Chang-shui Yu

       Complementarity relations of the measurement-induced average total coherence 

       Physica Scripta 94,  025102 (2019).

    94) Shao-xiong Wu,  Chang-shui Yu

       Quantum speed limit for initial mixed state.

       Phys. Rev. A  98,  042132 (2018).

    93)Bao-qing Guo, Tong Liu, and Chang-shui Yu

      Quantum thermal transistor based on the qubit-qutrit coupling 

       Phys. Rev. E  98,  022118 (2018).

    92) Tong Liu, Bao-Qing Guo, Yang Zhang, and Chang-shui Yu

      One-step implementation of a multi-target-qubit controlled phase gate in a multi-resonator circuit QED 

      System. 

     Quant. Inf. Proc. 17, 240 (2018).

    91) Sohaih Shah, Yang Zhang, G. Bari, Chang-shui Yu

        Tunable OMIT and Fano resonances in the optomechanical system with levitated nano-particle  

        IJTP 57(9):2814 (2018).

    90) Yang Zhang, Tong Liu, Shao-xiong Wu, Chang-shui Yu

        Optical response mediated by a two level system in the hybrid Optomechanical system.

        Quant. Inf. Proc. 17, 209 (2018).

    89) Jiasen Jin, and Chang-shui Yu

         Non-Markovianity in a collision model with environmental block.

        New J. Phys. 20, 053026 (2018)

    88) Li-qiang Zhang, Ting-ting Ma, Chang-shui Yu

        Measurement-induced non-locality in terms of the inverse approximate joint diagonalization .

       Phys. Rev. A 97, 032112 (2018).

    87) Tong Liu, Bao-qing Guo, Chang-shui Yu, Wei-Ning Zhang

        One-step implementation of a hybrid Fredkin gate with quantum memories and single superconducting. qubit in circuit QED and its applications.

       Opt. Exp. 26, 4498 (2018).

    86) Shaoxiong Wu, Yang Zhang, Chang-shui Yu

       Local quantum uncertainty guarantees the measurement precision for two coupled two-level systems in  

        non-Markovian environment.

       Annals of Phys. 390 71 (2018).

    85) Haiqing Zhao, Chang-shui Yu

       Remedying the strong monotonicity of the coherence measure in terms of the Tsallis relativity $\alpha$ entropy

       Sci. Rep. 8, 299 (2018).

    84) Si-ren Yang, Chang-shui Yu

       Operational resource theory of total coherence.

       Annal of Physics 388, 305 (2018).

    83) X. L. Zhao, Z. C. Shi, Chang-shui Yu, X. X. Yi, 

       Influence of localization transition on dynamical properties for an extended Aubry-Andre-Harper model

       J. Phys. B-Atom Mol. Opt. Phys. 50, 235503 (2017).

    82) Zi-chen He, Xin-yun Huang, Chang-shui Yu

       Enabling the self-contained refrigerator to work beyond its limits by filtering the reservoirs.

        Phys. Rev. E 96, 052126 (2017).

    81) Tong Liu, Chui-ping Yang, Yang Zhang, Chang-shui Yu,Wei-ning Zhang,

         Circuit QED: Cross-Kerr-effect induced by a superconducting qutrit without classical pulses.

         Quant. Inf. Proc. 16, 209 (2017).

    80) X. L. Zhao, Z. C. Shi, Chang-shui Yu, X. X. Yi, 

          Effect of loss on the topological features of dimer chains described by the extended Aubry-Andre-

          Harper model.

         Phys. Rev. A 95, 02337 (2017).

    79) Sohail Shah, Yang Zhang, Muhammad UsmanChang-shui Yu,

          Controllable optomechanically induced transparency in coupled optomechanical systems. 

         Euro. Phys. J. D 71,103 (2017).

    78) Chang-shui Yu,

          Quantum coherence via skew information and its polygamy.   

         Phys. Rev. A 95, 042337 (2017).

    77) Tong Liu, Chang-shui Yu,Wei-ning Zhang, 

         Deterministic transfer of an unknown qutrit state assisted by the low- Q microwave resonators

       Phys. Letts. A 381, 1727 (2017).

    76) Jun Zhang, Si-ren Yang,Yang Zhang, Chang-shui Yu,

          The classical correlation limits the ability of measurement-induced average coherence.

          Sci. Rep. 7, 45598 (2017).

    75) Jun Zhang, Yang Zhang, Chang-shui Yu,

          Stronger uncertainty relations with improvable upper and lower bounds.  

          Quant. Inf. Proc. 16, 131 (2017).

    74) Shao-xiong Wu, Chang-shui Yu,

         The Precision of Parameter estimation for dephasing model under squeezed reservoir.

        Int. J. Quant. Inf. 56, 1198 (2017).

    73) Yang Zhang, Sohail  Shah, Chang-shui Yu,

          Perfect photon absorption in hybrid atom-optomechanical system.

        Europhys. Lett. 115, 64002 (2016).

    72) Yang Zhang, Jun Zhang, Chang-shui Yu,

         Optimal photon blockade on the maximal atomic coherence.

      Int. J. Theor. Phys 55, 5239 (2016).

    71) Chang-shui Yu, Ting-ting Shao, Dong-mo Li,

         Distribution of standard deviation of an observable among superposed states.

         Annals of Physics 373, 43 (2016).

    70) Chang-shui Yu, Si-ren Yang and Bao-qing Guo,

         Total quantum coherence and its applications.

      Quant. Inf. Proc. 15, 3773 (2016).

    69) Sohail Shah, Yang Zhang, Jun Zhang, Chang-shui Yu,

         Optomechanically induced transparency in multi-cavity optomechanical system with and without one. two-level atom.

     Scientific Reports 6, 28830 (2016).

    68) Jun Zhang, Yang Zhang, Chang-shui Yu,

      The measurement-disturbance relation and the disturbance trade-off relation in terms of relative entropy. 

    Int. J. Theor. Phys 55, 3949 (2016).

    67) Yang Zhang, Jun Zhang, Chang-shui Yu,

      Photon statistics on the extreme entanglement.

      Scientific Reports 6, 24098 (2016).

    66) Chang-shui Yu, Bao-qing Guo, Si-ren Yang,

       Measurable genuine tripartite entanglement of (2*2*n)- dimensional quantum states via only two-fold copies.

       Phys. Rev. A 93, 042304 (2016).

    65) Shaoxiong Wu, Jun Zhang, Chang-shui Yu, He-shan Song,

         Weak measurements destroy too much quantum correlation.

        Int. J. Theor. Phys. 55 (1), 62 (2016).

    64) Yang Zhang,  Jun Zhang, Chang-shui Yu,

         Multistability in the coupled semiconductor microcavities.

          Int. J. Quant. Inf. 13 (7), 1550053 (2015).

    63) Yang Zhang,  Jun Zhang, Chang-shui Yu,

      Center-of-mass motion induced photon blockade.

       Annals of Physics 361, 563(2015).

    62) Jun Zhang, Yang Zhang, Chang-shui Yu,

    Entropy uncertainty relation with multiple measurements in the presence of memory.

    Scientific Reports 5,11701(2015).

    61) Shao-xiong Wu, Chang-shui Yu and He-shan Song,

       Effects of the reservoir squeezing on the precision of parameter estimation.

       Phys. Lett. A 379 (18-19), 1228(2015).

    60) Yahong Wang, Chang-shui Yu,

       Minimum remote state preparation of an arbitrary two-level one-atom state via cavity QED.

       Int. J. Quant. Inf. 13 (2), 1550009(2015).

    59) Jun Zhang, Shaoxiong Wu and Chang-shui Yu, Xiaoguang Wang,

         Analytic Symmetric Information-theoretical Discord for One Class of Two-qubit States.

        Int. J. Quant. Inf. 13 (1), 1550006(2015).

    58) Jun Zhang, Yang Zhang, Chang-shui Yu,

    Renyi entropy uncertainty relation for successive projective measurements.

    Quant. Inf. Proc. 14, 2239 (2015).

    57) Lin Wang, Chang-shui Yu,

    Heat current and quantum correlation subject to squeezing reservoirs.

     Int. J. Theor. Phys. 54 (8), 2942 (2015).

    56) Shao-xiong Wu, Yang Zhang, Chang-shui Yu and He-shan Song,

     Initial-state dependence in quantum speed limit.

      J. Phys. A: Gen. Maths. 48,045301 (2015).

    55) Jun Zhang, Yang Zhang, Chang-shui Yu,

        The role of quantum correlation in the quantum cloning.

        Euro. Phys. J. D 68, 365 (2014).

    54) Chang-shui Yu, Qi-yao Zhu,

    Re-examinaing the self-contained refrigerator in the strong coupling regime.

    Phys.Rev.E 90, 052142 (2014).

    53)Jun Zhang, Shaoxiong Wu, Chang-shui Yu,

         Quantum correlation cost of the weak measurement.

        Annals of Physics. 351, 104 (2014).

    52) Chang-shui Yu, Shaoxiong Wu, Xiaoguang Wang, X. X. Yi and He-shan Song,

         Quantum correlation measure in arbitrary bipartite systems.

        Euro physics. Lett. 107, 10007 (2014).

    51) Chang-shui Yu, Yang Zhang and Haiqing Zhao,

         Quantum correlation via coherence.

        Quant. Inf. Proc. 13 (6), 1437 (2014).

    50) Shaoxiong Wu, Jun Zhang,  Chang-shui Yu, He-shan  Song,

         Measurement induced nonlocality based on skew information.

        Phys. Lett. A. 378 (4), 344 (2014).

    49) Lin Wang, Chang-shui Yu,

         The role of a quantum channel on a quantum state.

       Int. J. Theor. Phys. 53 (2), 715 (2014).

    48) Chang-shui Yu, Bo Li and H. Fan,

        Sudden changes of quantum correlation.

    Quant. Inf. & Comp14(5&6),0454 (2014).

    47) Jun Zhang, Yang Zhang, Shaoxiong Wu and Chang-shui Yu,

         Non-classicalities via local disturbance of unitary operations.

        Euro. Phys. J. D. 67, 217 (2013).

    46) Zhenni Li, Chang-shui Yu, Shuxue Ding, and Zunyi Tang,

         Nondestructive Probing Scheme of Quantum State without Quantum Correlation

        Int. J. Theo. Phys. 52, 3676 (2013).

    45) Shao-xiong Wu, Jun Zhang, Chang-shui Yu, and He-shan Song,

         Quantum correlation can improve the distillation efficiency.

         Int. J. Quant. Inf. 11, 1350029 (2013).

    44) Jia-sen JinZhen-ni LiChang-shui Yu, and He-shan Song,

       Nondestructive detection of atomic Werner state with fiber-taper-coupled microsphere cavity.

       Physica A: Stat. Mech. its App. 392, 2830 (2013).

    43) Chang-shui Yu,  X. X. Yi, He-shan Song and Heng Fan,

         Entangling power in the deterministic quantum computation with one qubit.

        Phys. Rev. A 87, 022322 (2013).

    42) Chang-shui Yu, Jia-sen Jin, Heng Fan and He-shan Song,

         Dual roles of quantum discord in the robust and non-demolition probing.

         Phys. Rev. A 87, 022113 (2013).

    41) Chang-shui Yu,  Jun Zhang and Heng Fan,

         Quantum dissonance is rejected in a scheme of quantum overlap measurement.

      Phys. Rev. A 82, 052317 (2012).

    40) Zhen-ni Li, Chang-shui Yu,

        Probing Bell Diagonal State without Disturbing its correlations.

    Comm. in Theo. phys. 58, 47 (2012). 

    39) Shaoxiong WuChang-shui Yu,

         Localized quadripartite entanglement.

        Phys. Rev. A 85, 032332 (2012).

    38) Jia-sen JinChang-shui Yu, and He-shan Song,

         Measurable geometric quantum discord.

    J. Phys. A: Gen. Maths. 45,115308 (2012).

    37) Chang-shui Yu, and Haiqing Zhao,

         Direct Measure of quantum correlation.

    Phys. Rev. A 84, 062123  (2011).

    36) Jia-sen Jin, Chang-shui Yu, and He-shan Song,

         Nondestructive identification of the Bell diagonal state. 

    Phys. Rev. A 83, 032109 (2011).

    35) Zhen-ni Li, Jia-sen Jin, Chang-shui Yu,

         Probing quantum entanglement, quantum discord, classical correlation, and the quantum state without    

         disturbing them.

    Phys. Rev. A 83, 012317 (2011).

    34) Jia-sen Jin, Chang-shui Yu, Pei Pei, and He-shan Song,

        Quantum nondemolition measurement of the Werner state.

    Phys. Rev. A 82, 042112 (2010).

    33) Jia-sen Jin, Chang-shui Yu, Pei Pei, and He-shan Song,

        Quantum discord induced by white noises.

    J. Opt. Soc. Am. B-Opt. Phys. 27(9), 1799 (2010).

    32) Kai-hua Ma, Chang-shui Yu, and He-shan Song,

        A tight bound on negativity of superpositions.

    Eur. Phys. J. D  59(2), 317 (2010).

    31) Jia-sen Jin, Chang-shui Yu, Pei Pei, and He-shan Song,

        Positive effect of scattering strength of a microtoroidal cavity on atomic entanglement evolution. 

    Phys. Rev. A 81, 042309 (2010).

    30) Chang-shui Yu, Kai-hua Ma, He-shan Song,

    Observable Estimation of Bipartite Mixed-state Entanglement.

    Eur. Phys. J. D. 56(3), 431 (2010). 

    29Chang-shui Yu and He-shan Song,

    Bipartite concurrence and localized coherence.

      Phys. Rev. A 80, 022324 (2009).

    28) Chang-shui Yu and He-shan Song,  

       Describing a quantum channel by state tomography of a single probe state.

      Europhysics Letters 86(4), 40007 (2009).

    27)  Jin JS, Yu CS, Song HS,

       Scheme for state-independent teleportation between two distant atoms.

       Int. J. Quant. Inf. 7(4), 821(2009).

    26) Chang-shui Yu and He-shan Song,

       Monogamy and entanglement in tripartite quantum states.

      Phys. Letts. A 373(7), 727(2009).

    25)  Chang-shui Yu, X. X. Yi, and He-shan Song,

         Evolution of entanglement for quantum mixed states. 

         Phys. Rev. A 78, 062330 (2008).

    24) Wang XG, Yu CS, Yi XX,

       An alternative quantum fidelity for mixed states of qudits. 

        Phys. Letts. A 373(1), 58 (2008).

    23) Chang-shui Yu, X. X. Yi and He-shan Song, 

    Bounds on bipartitely shared entanglement reduced from superposed tripartite quantum states.

       Eur. Phys. J. D 49, 273  (2008).

    22) Chang-shui Yu, H. T. Cui and He-shan Song,

       Genuine tripartite entanglement and quantum phase transition. 

    Chinese Physics 17 (8), 2795 (2008).

    21) Chang-shui Yu, X. X. Yi, He-shan Song and D. Mei, 

    Preparation of a stable and maximally entangled state of two distant qutrits trapped in separate cavities. 

         Eur. Phys. J. D. 48 (3), 411(2008).

    20) Yahong Wang, He-shan Song and Chang-shui Yu,

     Faithful Controlled Teleportation of an Arbitrary Unknown Two-Atom State via Special W-States and QED Cavity. 

          Communication of Theoretical Physics, 45(9): 1199(2008).  

    19) Chang-shui Yu and He-shan Song,

    Entanglement monogamy of tripartite quantum states.

         Phys. Rev. A 77032329 (2008).

    18) Chang-shui Yu, L. Zhou and He-shan Song, 

    Genuine tripartite entanglement monotone of (2X2Xn) -dimensional systems.

      Phys. Rev. A 77, 022313 (2008).

    17) Chang-shui Yu, C. Li and He-shan Song, 

    Measurable concurrence of mixed states.

    Phys. Rev. A 77, 012305 (2008).

    16)Chang-shui Yu and He-shan Song,

    Measurable entanglement for tripartite quantum pure states.

    Phys. Rev. A 76, 022324 (2007).

    15) Chang-shui Yu, He-shan Song and Ya-hong Wang, 

    Genuine tripartite entanglement semi-monotone for (2 x 2 x n)-dimensional systems.

     Quantum information and computation, 7 (7), 584 (2007). 

    14) Chang-shui Yu, Ya-hong Wang and He-shan Song, 

    Teleportations of mixed states and multipartite quantum states, 

        Communications in Theoretical Physics, 47(6),1041 (2007).

    13) Chang-shui Yu, X. X. Yi, He-shan Song, et al, 

    Robust preparation of Greenberger-Horne -Zeilinger and W states of three distant atoms. 

    Phys. Rev. A 75, 044301 (2007). 

    12) Chang-shui Yu and He-shan Song,

     Full separability criterion for tripartite quantum systems.

         Eur.Phys.J.D.  42,147 (2007). 

    11) Chang-shui Yu, X. X. Yi and He-shan Song,

    Concurrence of Superpositions.

    Phys. Rev. A. 75, 022332(2007). 

    10) WANG Ya-Hong, YU Chang-Shui, and SONG He-Shan, 

    Teleportation of an Arbitrary Multipartite GHZ-Class State by One EPR Pair.

    Chinese Physics Letters, 23 (12), 3142 (2006). 

    9) CHEN Jing, YU Chang-Shui, and SONG He-Shan,

     Elementary Quantum Gates Based on Intrinsic Interaction Hamiltonian. 

      Communications in Theoretical Physics, 46(1),69 (2006). 

    8) Chang-shui Yu and He-shan Song,

         Existence Criterion of Genuine Tripartite Entanglement. 

    Phys. Rev. A 73, 032322 (2006).

    7) Chang-shui Yu and He-shan Song,

    Global Entanglement for Multipartite Quantum States. 

    Phys. Rev. A 73, 022325 (2006). 

    6) Chang-shui Yu, He-shan Song and Ya-hong Wang,

     Remote Preparation of a Qudit Using Maximally Entangled States of Qubits. 

    Phys. Rev. A 73, 022340 (2006). 

    5) Chang-shui Yu and He-shan Song,

    Separability criterion of Tripartite Qubit Systems.

     Phys. Rev. A 72, 022333 (2005). 

    4) Chang-shui Yu and He-shan Song, 

    Multipartite Entanglement Measure. 

    Phys. Rev. A 71, 042331 (2005).

    3) Chang-shui Yu and He-shan Song,

    Generalization of Concurrence Vectors.

    Phys. Letts. A 333 , 364 (2004).  

    2) Chang-shui Yu and He-shan Song,

     Free Entanglement Measure of Multiparticle systems.

    Phys. Letts. A 330 ,377 (2004).

    1) X. X. Yi, Chang-shui Yu, L. Zhou and He-shan Song,

    Noise-assisted preparation of entangled atoms.

    Phys. Rev. A, 68, 052304 (2003).        

      

    Note:

          5)- 8),11), 13),16)-19),25), 29)

         were selected for the issues of Virtual Journal of Quantum Information.

    16),17),29) were selected for the issue of Virtual Journal of Nanoscale Science & Technology.