PIRSA:14040066

Quantum thermalization and many-body Anderson localization

APA

Huse, D. (2014). Quantum thermalization and many-body Anderson localization. Perimeter Institute for Theoretical Physics. https://pirsa.org/14040066

MLA

Huse, David. Quantum thermalization and many-body Anderson localization. Perimeter Institute for Theoretical Physics, Apr. 30, 2014, https://pirsa.org/14040066

BibTex

          @misc{ scivideos_PIRSA:14040066,
            doi = {10.48660/14040066},
            url = {https://pirsa.org/14040066},
            author = {Huse, David},
            keywords = {Quantum Foundations},
            language = {en},
            title = {Quantum thermalization and many-body Anderson localization},
            publisher = {Perimeter Institute for Theoretical Physics},
            year = {2014},
            month = {apr},
            note = {PIRSA:14040066 see, \url{https://scivideos.org/pirsa/14040066}}
          }
          

David Huse Princeton University

Talk numberPIRSA:14040066
Source RepositoryPIRSA
Collection

Abstract

Progress in physics and quantum information science motivates much recent study of the behavior of strongly-interacting many-body quantum systems fully isolated from their environment, and thus undergoing unitary time evolution. What does it mean for such a system to go to thermal equilibrium? I will explain the Eigenstate Thermalization Hypothesis (ETH), which posits that each individual exact eigenstate of the system's Hamiltonian is at thermal equilibrium, and which appears to be true for most (but not all) quantum many-body systems. Prominent among the systems that do not obey this hypothesis are quantum systems that are many-body Anderson localized and thus do not constitute a reservoir that can thermalize itself. When the ETH is true, one can do standard statistical mechanics using the `single-eigenstate ensembles', which are the limit of the microcanonical ensemble where the `energy window' contains only a single many-body quantum state. These eigenstate ensembles are more powerful than the traditional statistical mechanical ensembles, in that they can also "see" the quantum phase transition in to the localized phase, as well as a rich new world of phases and phase transitions within the localized phase.