Designing 3D Dirac materials for dark matter detectors using density functional theory

ORAL

Abstract

Light dark matter has been postulated to both scatter and excite electrons in a Dirac semimetal. However, the cross section depends strongly on the band gap, Fermi velocities and cone degeneracy in the material. Here we use first-principles calculations to propose materials that fulfil these criteria. We also discuss how these properties can be engineered with chemistry and pressure, thus optimizing the dark matter interaction criteria in a 3D Dirac material[1].
[1] Y. Hochberg et al., arXiv:1708.08929 (2017)

Presenters

  • Sinead Griffin

    • Lawrence Berkeley Natl Lab
    • Department of Physics, Univ of California - Berkeley

Authors

  • Sinead Griffin

    • Lawrence Berkeley Natl Lab
    • Department of Physics, Univ of California - Berkeley

  • Zhenfei Liu

    • Department of Physics, UC Berkeley and Molecular Foundry, Lawrence Berkeley National Lab
    • Lawrence Berkeley Natl Lab
    • Lawrence Berkeley National Laboratory

  • Kathryn Zurek

    • Lawrence Berkeley Natl Lab

  • Jeffrey Neaton

    • Molecular Foundry, Lawrence Berkeley National Laboratory; Department of Physics, University of California, Berkeley; Kavli Energy Nanosciences Institute at Berkeley
    • Physics, University of California, Berkeley; Lawrence Berkeley National Laboratory
    • Department of Physics, University of California
    • Univ of California - Berkeley
    • Lawrence Berkeley Natl Lab
    • Materials Science Division, Lawrence Berkeley National Laboratory
    • Molecular Foundry, Lawrence Berkeley National Lab
    • Physics, University of California, Berkeley
    • Department of Physics UCB; Molecular Foundry LBNL; Kavli ENSI
    • Lawrence Berkeley National Laboratory
    • Department of Physics, Univ of California - Berkeley
    • Lawrence Berkeley National Lab and University of California - Berkeley