Nature Communications (Feb 2024)

Dual Higgs modes entangled into a soliton lattice in CuTe

  • SeongJin Kwon,
  • Hyunjin Jung,
  • SangJin Lee,
  • Gil Young Cho,
  • KiJeong Kong,
  • ChoongJae Won,
  • Sang-Wook Cheong,
  • Han Woong Yeom

DOI
https://doi.org/10.1038/s41467-024-45354-4
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 6

Abstract

Read online

Abstract Recently discovered Higgs particle is a key element in the standard model of elementary particles and its analogue in materials, massive Higgs mode, has elucidated intriguing collective phenomena in a wide range of materials with spontaneous symmetry breaking such as antiferromagnets, cold atoms, superconductors, superfluids, and charge density waves (CDW). As a straightforward extension beyond the standard model, multiple Higgs particles have been considered theoretically but not yet for Higgs modes. Here, we report the real-space observations, which suggest two Higgs modes coupled together with a soliton lattice in a solid. Our scanning tunneling microscopy reveals the 1D CDW state of an anisotropic transition metal monochalcogenide crystal CuTe is composed of two distinct but degenerate CDW structures by the layer inversion symmetry broken. More importantly, the amplitudes of each CDW structure oscillate in an out-of-phase fashion to result in a regular array of alternating domains with repeating phase-shift domain walls. This unusual finding is explained by the extra degeneracy in CDWs within the standard Landau theory of the free energy. The multiple and entangled Higgs modes demonstrate how novel collective modes can emerge in systems with distinct symmetries broken simultaneously.