Dynamical Scaling and Planckian Dissipation Due to Heavy-Fermion Quantum Criticality

被引:0
|
作者
Gleis, Andreas [1 ,2 ]
Lee, Seung-Sup B. [1 ,3 ,4 ,5 ]
Kotliar, Gabriel [2 ,6 ]
Von Delft, Jan [1 ]
机构
[1] Arnold Sommerfeld Center for Theoretical Physics, Center for NanoScience, Munich Center for Quantum Science and Technology, Ludwig-Maximilians-Universität München, Munich,80333, Germany
[2] Department of Physics and Astronomy, Rutgers University, Piscataway,NJ,08854, United States
[3] Department of Physics and Astronomy, Seoul National University, Seoul,08826, Korea, Republic of
[4] Center for Theoretical Physics, Seoul National University, Seoul,08826, Korea, Republic of
[5] Institute for Data Innovation in Science, Seoul National University, Seoul,08826, Korea, Republic of
[6] Condensed Matter Physics and Materials Science Department, Brookhaven National Laboratory, Upton,NY,11973, United States
来源
Physical Review Letters | 2025年 / 134卷 / 10期
关键词
Cesium alloys - Cobalt alloys - Magnetic susceptibility - Optical depth - Quantum optics;
D O I
10.1103/PhysRevLett.134.106501
中图分类号
学科分类号
摘要
We study dynamical scaling associated with a Kondo-breakdown quantum-critical point (KB QCP) of the periodic Anderson model, treated by two-site cellular dynamical mean-field theory (2CDMFT). In the quantum-critical region, the dynamical staggered-spin susceptibility exhibits ω/T scaling. We propose a scaling ansatz that describes this behavior and reveals Planckian dissipation for the longest-lived excitations. The current susceptibility follows the same scaling, leading to strange-metal behavior for the optical conductivity and resistivity. Importantly, this behavior is driven by strong short-ranged vertex contributions, not single-particle decay. This suggests that the KB QCP described by 2CDMFT is a novel intrinsic (i.e., disorder-free) strange-metal fixed point. Our results for the optical conductivity match experimental observations on YbRh2Si2 and CeCoIn5. © 2025 authors. Published by the American Physical Society.
引用
收藏
相关论文
共 50 条
  • [1] Quantum criticality in heavy-fermion metals
    Philipp Gegenwart
    Qimiao Si
    Frank Steglich
    Nature Physics, 2008, 4 : 186 - 197
  • [2] Quantum criticality in heavy-fermion metals
    Gegenwart, Philipp
    Si, Qimiao
    Steglich, Frank
    NATURE PHYSICS, 2008, 4 (03) : 186 - 197
  • [3] Unconventional Quantum Criticality in Heavy-Fermion Compounds
    Stockert, O.
    Steglich, F.
    ANNUAL REVIEW OF CONDENSED MATTER PHYSICS, VOL 2, 2011, 2 : 79 - 99
  • [4] Antiferromagnetic criticality at a heavy-fermion quantum phase transition
    Knafo, W.
    Raymond, S.
    Lejay, P.
    Flouquet, J.
    NATURE PHYSICS, 2009, 5 (10) : 753 - 757
  • [5] Novel types of quantum criticality in heavy-fermion systems
    Gegenwart, P.
    Steglich, F.
    Geibel, C.
    Brando, M.
    EUROPEAN PHYSICAL JOURNAL-SPECIAL TOPICS, 2015, 224 (06): : 975 - 996
  • [6] Novel types of quantum criticality in heavy-fermion systems
    P. Gegenwart
    F. Steglich
    C. Geibel
    M. Brando
    The European Physical Journal Special Topics, 2015, 224 : 975 - 996
  • [7] Antiferromagnetic criticality at a heavy-fermion quantum phase transition
    W. Knafo
    S. Raymond
    P. Lejay
    J. Flouquet
    Nature Physics, 2009, 5 : 753 - 757
  • [8] Quantum criticality of the heavy-fermion compound YbAuCu4
    Yamamoto, Aya
    Wada, Shinji
    Sarrao, John L.
    JOURNAL OF THE PHYSICAL SOCIETY OF JAPAN, 2007, 76 (06)
  • [9] SCALING IN HEAVY-FERMION SYSTEMS
    THOMPSON, JD
    LAWRENCE, JM
    FISK, Z
    JOURNAL OF LOW TEMPERATURE PHYSICS, 1994, 95 (1-2) : 59 - 74
  • [10] Heavy-fermion quantum criticality and destruction of the Kondo effect in a nickel oxypnictide
    Luo, Yongkang
    Pourovskii, Leonid
    Rowley, S. E.
    Li, Yuke
    Feng, Chunmu
    Georges, Antoine
    Dai, Jianhui
    Cao, Guanghan
    Xu, Zhu'an
    Si, Qimiao
    Ong, N. P.
    NATURE MATERIALS, 2014, 13 (08) : 777 - 781
12345