English

Tunable excitonic insulator in quantum limit graphite

Materials Science 2017-05-23 v1 Mesoscale and Nanoscale Physics

Abstract

Half a century ago, Mott noted that tuning the carrier density of a semimetal towards zero produces an insulating state in which electrons and holes form bound pairs. It was later argued that such pairing persists even if a semiconducting gap opens in the underlying band structure, giving rise to what has become known as the strong coupling limit of an `excitonic insulator.' While these `weak' and `strong' coupling extremes were subsequently proposed to be manifestations of the same excitonic state of electronic matter, the predicted continuity of such a phase across a band gap opening has not been realized experimentally in any material. Here we show the quantum limit of graphite, by way of temperature and angle-resolved magnetoresistance measurements, to host such an excitonic insulator phase that evolves continuously between the weak and strong coupling limits. We find that the maximum transition temperature T_EI of the excitonic phase is coincident with a band gap opening in the underlying electronic structure at B_0= 46 +/- 1 T, which is evidenced above T_EI by a thermally broadened inflection point in the magnetoresistance. The overall asymmetry of the observed phase boundary around B_0 closely matches theoretical predictions of a magnetic field-tuned excitonic insulator phase in which the opening of a band gap marks a crossover from predominantly momentum-space pairing to real-space pairing.

Keywords

Cite

@article{arxiv.1508.03645,
  title  = {Tunable excitonic insulator in quantum limit graphite},
  author = {Z. Zhu and R. D. McDonald and A. Shekhter and B. J. Ramshaw and K. A. Modic and F. F. Balakirev and N. Harrison},
  journal= {arXiv preprint arXiv:1508.03645},
  year   = {2017}
}

Comments

11 pages, including 4 figures

R2 v1 2026-06-22T10:34:11.396Z