Phonon Quantum Phase Transition

ORAL

Abstract

The emergence of novel quantum phenomena is often shown in materials close to a zero temperature phase transition. Much of the effort to study these new effects, like Kondo entanglement and its breakdown in heavy-fermion metals, has been focused mainly in fermionic systems. Here, we demonstrate that a phonon (bosonic) system can exhibit a quantum phase transition with dislocations. The quantum critical point (QCP) reached by the phonons arises at a second-order transition between two-ground states corresponding to a conventional phonon state (symmetric phase) and a dynamically-induced dipole field (symmetry-broken phase), at zero temperature. The distinct ground states arise from a competition between the phonon-dislocation anharmonic interaction and the topological nature of the dislocation. Furthermore, through renormalization group analysis, this phonon system provides a very different type of quantum critically which can be used to tailor phonon transport at the single-mode level [arXiv:1809.06495].

*National Science Foundation Graduate Fellowship program under Grant No. 1122374. Defense Advanced Research Projects Agency Materials for Transduction (MATRIX) program, under Grant HR0011-16-2-0041, and Becalos Foundation.

Presenters

  • Ricardo Pablo Pedro

    • Massachusetts Institute of Technology
    • Nuclear Science and Engineering, Massachusetts Institute of Technology

Authors

  • Ricardo Pablo Pedro

    • Massachusetts Institute of Technology
    • Nuclear Science and Engineering, Massachusetts Institute of Technology

  • Nina Andrejevic

    • Massachusetts Institute of Technology
    • Department of Materials Science and Engineering, Massachusetts Institute of Technology
    • Materials Science and Engineering, Massachusetts Institute of Technology

  • Yoichiro Tsurimaki

    • Massachusetts Institute of Technology

  • Zhiwei Ding

    • Massachusetts Institute of Technology

  • Te-Huan Lu

    • Massachusetts Institute of Technology

  • Gerald D Mahan

    • Physics, Pennsylvania State University
    • Department of Physics, Pennsylvania State University

  • Shengxi Huang

    • Electrical Engineering and Computer Science, Pennsylvania State University
    • Massachusetts Institute of Technology

  • Mingda Li

    • Massachusetts Institute of Technology
    • Nuclear Engineering, Massachusetts Institute of Technology
    • Department of Nuclear Science and Engineering, Massachusetts Institute of Technology
    • Nuclear Science and Engineering, Massachusetts Institute of Technology