Visualizing 2d Wigner solid and it quantum melting

ORAL

Abstract

Two-dimensional strongly interacting electrons crystalize into a solid phase known as the Wigner crystal at low densities and form a Fermi liquid at high densities. At intermediate densities, the two-dimensional solid evolves into a strongly correlated liquid phase around a critical density. We observed this quantum melting of a disordered Wigner solid in bilayer molybdenum diselenide (MoSe2) using a noninvasive scanning tunneling microscopy imaging technique. At low densities, the Wigner solid forms nanocrystalline domains pinned by local disorder. It exhibits a quantum densification behavior with increased densities in the solid phase. Above a threshold density, the Wigner solid melts locally and enters a mixed phase in which solid and liquid regions coexist. The liquid regions expand and form a percolation network at even higher densities.

*This work was primarily funded by the US Department of Energy, Office of Science, Basic Energy Sciences, Materials Sciences and Engineering Division under contract DE-AC02-05-CH11231 within the van der Waals heterostructure program KCWF16 (device fabrication, STM spectroscopy, theoretical analysis, and computations). Support was also provided by the National Science Foundation award DMR-2221750 (surface preparation). This research used the Lawrencium computational cluster provided by the Lawrence Berkeley National Laboratory (supported by the US Department of Energy, Office of Basic Energy Sciences under contract DE-AC02-05-CH11231).

Publication: Ziyu Xiang et al. ,Imaging quantum melting in a disordered 2D Wigner solid.Science388,736-740(2025).DOI:10.1126/science.ado7136

Presenters

  • Ziyu Xiang

    • University of California, Berkeley

Authors

  • Ziyu Xiang

    • University of California, Berkeley

  • Hongyuan Li

    • Lawrence Berkeley National Laboratory

  • Jianghan Xiao

    • University of California, Berkeley
    • UC Berkeley

  • Michael F Crommie

    • University of California, Berkeley

  • feng wang

    • University of California, Berkeley