郭领阵 副教授 [English version]
办公地址:天津大学北洋园校区32教318室
电子邮箱:lingzhen_guo@tju.edu.cn
专业方向:量子光学,凝聚态理论,统计物理
通讯地址:天津市津南区雅观路135号天津大学北洋园校区32教318室
邮政编码:300350
个人简历:在北京师范大学相继完成本科和研究生教育并获得博士学位,期间于2010年9月至2012年8月在德国卡尔斯鲁厄理工大学(Karlsruhe Institute of Technology)理论固体研究所进行联合博士培养两年。2013年6月博士毕业后至2022年12月在德国卡尔斯鲁厄理工大学、瑞典查尔姆斯理工大学(Chalmers University of Technology)和德国马克斯·普朗克光学研究所(Max Planck Institute for the Science of Light)等单位做博士后研究,期间于2015年9月至2017年11月获得德国“卡尔·蔡司基金青年科学家”总额为20万欧元(时约150万人民币)的项目资助。2023年3月加入天津大学理学院 量子交叉研究中心,任北洋英才副教授。
研究方向
长期致力于超导量子器件和非平衡态系统的理论研究,提出了非马尔科夫巨原子模型,发展了光与物质非局域耦合理论;提出了相空间晶体理论并应用于玻色码量子信息处理;发展了量子多体退相干理论,非微扰解析计算了时域涨落。涉及的研究课题包括:
量子光学:超导线路量子电动力学、巨原子物理、约瑟夫森光子学、 光力体系、非马尔科夫光学等
量子信息:量子器件物理,、玻色码量子计算,、量子纠错、离子阱量子模拟等
非平衡态:弗洛凯物理、相空间晶体、时间晶体、拓扑物理、冷原子光晶格等
统计物理:量子多体退相干、本征态热化假说、动力学相变、量子混沌等
机器学习:人工神经网络、量子多体物理深度学习等
在以后的近几年里,拟重点开展关于容错性玻色码量子信息处理的研究,为提高超导量子器件信息处理功能和实现通用量子计算提供现实可行的方案。
论文专著
至2024年4月已发表(含已接收)30 篇SCI论文,以第一或通信作者发表1篇 Nature Physics、3篇 Phys. Rev. Lett.,有3篇文章入选美国物理学会(APS)物理学评论(Phys. Rev.)期刊系列的“编辑推荐”(Editors' Suggestion)文章。2021年受英国物理学会(IOP)邀请独立撰写出版一部约177页的英文学术专著。相关工作得到了国内外同行的广泛关注和跟进研究(谷歌学术引用超1000次,近五年引用超过900次),并得到了国内外多家知名媒体网站的报道(比如 Phys.org、蔻享学术)。
◉ 学术专著: 
【1】Lingzhen Guo,
Phase space crystals: Condensed matter in dynamical systems.
Bristol, UK: IOP Publishing (2021), 177 pages.
Online ISBN: 978-0-7503-3563-8 • Print ISBN: 978-0-7503-3561-4
◉ 学位论文:
【1】硕士论文:受驱动介观达芬振子的量子动力学研究,2009年
【2】博士论文:Quantum Effects in Driven Nonliear Systems,2013年
◉ 期刊论文及预印本(*第一作者,#通信作者):
◾ 代表作:
【I】Giant acoustic atom: A single quantum system with a deterministic time delay,
LG*, Arne Grimsmo, Anton Frisk Kockum, Mikhail Pletyukhov and Goran Johansson,
Phys. Rev. A 95 , 053821 (2017) (Editors' Suggestion ).【引用132次,谷歌学术统计至2024年4月】
【II】Oscillating bound states for a giant atom,
LG*#, A. F. Kockum , F. Marquardt and G. Johansson,
Phys. Rev. Research 2, 043014 (2020).【引用110次,谷歌学术统计至2024年4月】
【III】Nonexponential decay of a giant artificial atom,
Gustav Andersson*, Baladitya Suri, LG#, Thomas Aref, Per Delsing#,
Nature Physics 15, 1123 (2019).【引用166次,谷歌学术统计至2024年4月】
【IV】Phase Space Crystals: A New Way to Create a Quasienergy Band Structure,
LG*, Michael Marthaler and Gerd Schoen,
Phys. Rev. Lett. 111 , 205303 (2013) (Editor's suggestion).【引用90次,谷歌学术统计至2024年4月】
【V】Engineering Arbitrary Hamiltonians in Phase Space,
LG*# and Vittorio Peano,
Phys. Rev. Lett. 132 , 023602 (2024)
【VI】Many-Body Dephasing in a Trapped-Ion Quantum Simulator,
H. B. Kaplan*, LG*#, W. Lin Tan, A. De, Florian Marquardt, Guido Pagano, Christopher Monroe#,
Phys. Rev. Lett. 125, 120605 (2020).【引用33次,谷歌学术统计至2024年4月】
【VII】Phase Space Crystal Vibrations: Chiral Edge States with Preserved Time-reversal Symmetry,
LG*#, Vittorio Peano#, Florian Marquardt,
Phys. Rev. B, 105, 094301 (2022) (Editor’s suggestion).
◾ 量子光学和量子信息方向:
【20】 Catch and release of propagating bosonic field with non-Markovian giant atom,
Luting Xu and LG#,
New J. Phys. 26 013025 (2024)
【19】 Giant Emitters in a Structured Bath with Non-Hermitian Skin Effect,
Lei Du, LG, Yan Zhang, and Anton Frisk Kockum,
Phys. Rev. Research 5, L042040 (2023)
【18】 Giant-atom effects on pop. and entang. dynamics of Rydberg atoms in the opt. regime,
Yao-Tong Chen, Lei Du, Yan Zhang, LG, Jin-Hui Wu, M. Artoni, and G. C. La Rocca
Phys. Rev. Research 5, 043135 (2023).
【17】Engineering Arbitrary Hamiltonians in Phase Space,
LG*# and Vittorio Peano,
Phys. Rev. Lett. 132 , 023602 (2024)
【16】 Complex decoherence-free interactions between giant atoms,
Lei Du, LG, Yong Li,
Phys. Rev. A 107, 023705 (2023).
【15】 Nonreciprocal and chiral single-photon scattering for giant atoms,
Yao-Tong Chen, Lei Du, LG, Zhihai Wang, Yan Zhang, Yong Li, Jin-Hui Wu,
Communications Physics 5, 215 (2022).
【14】 Oscillating bound states for a giant atom,
LG*#, A. F. Kockum , F. Marquardt and G. Johansson,
Phys. Rev. Research 2, 043014 (2020).
【13】 Nonexponential decay of a giant artificial atom,
Gustav Andersson*, Baladitya Suri, LG#, Thomas Aref, Per Delsing#,
Nature Physics 15, 1123(2019).
【12】 Giant acoustic atom: A single quantum system with a deterministic time delay,
LG*, Arne Grimsmo, Anton Frisk Kockum, Mikhail Pletyukhov and Goran Johansson,
Phys. Rev. A 95 , 053821 (2017) (Editors' Suggestion ).
【11】Probing the Tavis-Cummings level splitting with intermediate-scale superconducting circuits,
P. Yang, J. Brehm, J. Lepp., LG, M. Marthaler, I. Boventer, A. Stehli, T. Wolz, A. Ustinov, M. Weides,
Phys. Rev. Applied 14, 024025 (2020).
【10】Res. inversion in a superconducting cavity coupled to artificial atoms and a microwave background,
J. Leppakangas, J. Brehm, P. Yang, LG, M. Marthaler, A. V. Ustinov, M. Weides,
Phys. Rev. A 99, 063804 (2019).
【09】Local Sensing with the Multi-Level AC Stark Effect ,
A. Schneider, J. Braumller, LG, P. Stehle, H. Rotzinger, M. Marthaler, A. V. Ustinov, M. Weides,
Phys. Rev. A 97 , 062334 (2018).
【08】Scalable Ion Trap Architecture for Universal Quantum Computation by Collisions,
Pengfei Liang* and LG#,
arXiv:1801.02593 (2018).
【07】Multi-photon dressing of an anharmonic superconducting many-level quantum circuit,
J. B., J. C., S. Schlor, H. Rotz., L. Radt, A. Luka., P. Yang, M. Marthaler, LG, A. U. and M. Weides,
Phys. Rev. B 91 , 054523 (2015).
【06】Quantum critical temperature of a modulated oscillator,
LG*, V. Peano, M. Marthaler and M.I. Dykman,
Phys. Rev. A 87, 062117 (2013).
【05】Emission spectrum of the driven nonlinear oscillator,
Stephan Andre, LG, V. Peano, M. Marthaler, Gerd Schon,
Phys. Rev. A 85 , 053825 (2012).
【04】The role of damping for the driven anharmonic quantum oscillator,
LG*, Michael Marthaler, Stephan Andre, Gerd Schoen,
J. Phys.: Conf. Ser. 400, 042014 (2012).
【03】Dynamic Quantum Tunneling in Mesoscopic Driven Duffing Oscillators,
LG*, Z. Zheng, X.Q. Li and Y. Yan,
Phys. Rev. E 84, 011144 (2011).
【02】Deterministic creation and stabilization of entang. in cQED by homodyne-mediated feedb. cont.,
Z. Liu, L. Kuang, K. Hu, L. Xu, S. Wei, LG#, Xin-Qi Li#,
Phys. Rev. A 82 , 032335 (2010).
【01】Quantum Dynamics of Mesoscopic Driven Duffing Oscillators,
LG*, Zhigang Zheng, Xin-Qi Li#,
EPL (Europhysics Letters) 90, 10011 (2010).
◾ 非平衡凝聚态物理方向:
【07】Classical Phase Space Crystals in Open Environment,
Ali Emami Kopaei*, Krzysztof Sacha and LG#,
Phys. Rev. B 107, 214302 (2023).
【06】Phase Space Crystal Vibrations: Chiral Edge States with Preserved Time-reversal Symmetry,
LG*#, Vittorio Peano#, Florian Marquardt,
Phys. Rev. B, 105, 094301 (2022) (Editor’s suggestion).
【05】Condensed Matter Physics in Time crystals,
LG*#, Pengfei Liang,
New J. Phys. 22, 075003 (2020).
【04】Floquet Many-body Engineering: Topology and Many-body Physics in Phase Space Lattices,
Pengfei Liang*#, Michael Marthaler, LG#,
New J. Phys. 20 , 023043 (2018).
【03】Effec. Long-distance Interaction from Short-distance Interac. in Period. Driven 1D Classical System,
LG*#, Modan Liu and Michael Marthaler,
Phys. Rev. A 93 , 053616 (2016).
【02】Synthesizing Lattice Structures in Phase Space,
LG*# and Michael Marthaler,
New J. Phys. 18, 023006 (2016).
【01】Phase Space Crystals: A New Way to Create a Quasienergy Band Structure,
LG*, Michael Marthaler and Gerd Schoen,
Phys. Rev. Lett. 111 , 205303 (2013) (Editor's suggestion).
◾ 统计物理方向:
【02】Many-Body Dephasing in a Trapped-Ion Quantum Simulator,
H. B. Kaplan*, LG*#, W. Lin Tan, A. De, Florian Marquardt, Guido Pagano, Christopher Monroe#,
Phys. Rev. Lett. 125, 120605 (2020).
【01】Dynamical phase transitions in quantum spin models with antiferr. long-range interactions,
Jad C. Halimeh, Maarten Van Damme, LG, Johannes Lang, Philipp Hauke,
Phys. Rev. B 104, 115133 (2021).
◾ 机器学习方向:
【01】Deep Learning of Quantum Many-Body Dynamics via Random Driving,
N. Mohseni, T. Fösel, LG, C. Navarrete-Benlloch, F. Marquardt,
Quantum 6, 714 (2022).
研究生培养
计划每年招收1-2名硕士研究生 ,欢迎大家积极报考。
