English

Interlayer coupling driven phase evolution in hyperbolic $1T$-TaS$_2$

Strongly Correlated Electrons 2026-03-06 v1

Abstract

Understanding how microscopic interactions control macroscopic phase transitions is central to quantum materials, where charge density waves (CDWs), Mott states, and superconductivity often compete. In 1T1T-TaS2_2, this competition is tied to a sequence of CDW phases and a hysteretic metal-insulator transition, but details of the transition, especially the role of interlayer coupling, remain unresolved. In this work, spectroscopic ellipsometry is used to determine the uniaxial dielectric response of bulk 1T1T-TaS2_2 from room temperature down to the commensurate insulating state. The room-temperature data reveal natural type-II hyperbolic behavior in the visible range, with negative in-plane and positive out-of-plane permittivity. Temperature-dependent ellipsometry combined with anisotropic Bruggeman effective medium analysis shows that the metallic domains responsible for percolation evolve from disc-like to needle-like shapes, and that, upon heating, an additional intermediate phase emerges. These results identify the transition in 1T1T-TaS2_2 as a three-dimensional, interlayer-driven percolation process and establish this material as a natural, tunable hyperbolic medium.

Keywords

Cite

@article{arxiv.2512.07508,
  title  = {Interlayer coupling driven phase evolution in hyperbolic $1T$-TaS$_2$},
  author = {Achyut Tiwari and Bruno Gompf and Martin Dressel},
  journal= {arXiv preprint arXiv:2512.07508},
  year   = {2026}
}

Comments

15 pages, 11 figures

R2 v1 2026-07-01T08:14:47.644Z