Pappalardo Fellows

Pappalardo Fellow in Physics: 2019-2022

Mallika Randeria

Name: Mallika Randeria

Title: Pappalardo Fellow in Physics: 2019-2022


Phone: (617) 253-0577


MIT Department of Physics
77 Massachusetts Avenue, Room 13-2037
Cambridge, MA 02139

Related Links:

  • Pappalardo Fellowships at MIT
  • Area of Physics:

    Experimental Condensed Matter Physics

    Research Interests

    Mallika Randeria is excited by questions of how strong interactions give rise to new and unexpected quantum behavior in materials. Her PhD research has centered on imaging spontaneous symmetry breaking and investigating one-dimensional behavior at electronic domain boundaries in the quantum Hall regime. These experiments were performed using a scanning tunneling microscope, a unique instrument with atomic scale resolution, which provides local, microscopic information of sample surfaces. At MIT, Randeria is interested in exploring these ideas of emergent quantum phenomena in two-dimensional materials using complementary global measurement techniques including electronic transport.

    Randeria is also passionate about increasing the diversity in STEM fields by creating an empowering environment at both an institutional and individual level. She enjoys sharing her joy of science with the public and teaching nontraditional students.

    Biographical Sketch

      Mallika Randeria spent a large part of her childhood in Mumbai, India, interspersed with periods in the USA, before moving to Ohio, where she attended high school. Randeria received her undergraduate degree in physics from MIT and she completed her PhD in experimental condensed matter physics from Princeton University, working with Prof. Ali Yazdani.

    Selected Publications

    • Interacting multi-channel topological boundary modes in a quantum Hall valley system. M. T. Randeria, K. A. Agarwal, B. E. Feldman, H. Ding, H. Ji, R. J. Cava, S. A. Parameswaran, S.L. Sondhi, and A. Yazdani. Accepted in Nature (2019).
    • Ferroelectric quantum Hall phase revealed by visualizing Landau level wavefunction interference. M. T. Randeria, B. E. Feldman, F. Wu, H. Ding, A. Gyenis, H. Ji, R. J. Cava, A. H. MacDonald, and A. Yazdani. Nature Physics 14, 796 (2018).
    • Observation of a nematic quantum Hall liquid on the surface of bismuth. B. E. Feldman, M. T. Randeria, A. Gyenis, F. Wu, H. Ji, R. J. Cava, A. H. MacDonald, and A. Yazdani. Science 354, 316 (2016).
    • Scanning Josephson spectroscopy on the atomic scale. M. T. Randeria, B. E. Feldman, I. K. Drozdov, and A. Yazdani. Phys. Rev. B 93, R161115 (2016).
    • High-resolution studies of the Majorana atomic chain platform. B. E. Feldman, M. T. Randeria, J. Li, S. Jeon, Y. Xie, Z. Wang, I. K. Drozdov, B. A. Bernevig, and A. Yazdani, Nature Physics 13, 286 (2017).

    Last updated on October 18, 2019 10:44 AM