English

Charge Singlets and Orbital-Selective Charge Density Wave Transitions

Strongly Correlated Electrons 2022-09-15 v2

Abstract

The possibility of "orbitally selective Mott transitions" within a multiband Hubbard model, in which one orbital with large on-site electron-electron repulsion U1U_1 is insulating and another orbital, to which it is hybridized, with small U1U_{-1}, is metallic, is a problem of long-standing debate and investigation. In this paper we study an analogous phenomenon, the co-existence of metallic and insulating bands in a system of orbitals with different electron-phonon coupling (EPC). To this end, we examine two variants of the bilayer Holstein model: a uniform bilayer and a "Holstein-Metal interface" where the electron-phonon coupling, λ\lambda, is zero in the "metallic" layer. In the uniform bilayer Holstein model, charge density wave (CDW) order dominates at small interlayer hybridization t3t_3, but decreases and eventually vanishes as t3t_3 grows, providing a charge analog of singlet (spin liquid) physics. In the interface case, we show that CDW order penetrates into the metal layer and forms long-range CDW order at intermediate ratio of inter- to intra-layer hopping strengths, 1.4t3/t3.41.4 \lesssim t_3/t \lesssim 3.4. This is consistent with the occurrence of an "orbitally selective CDW" regime at weak t3t_3 in which the layer with λ10\lambda_{1} \neq 0 exhibits long-range charge order, but the "metallic layer" with λ1=0\lambda_{-1}=0, to which it is hybridized, does not.

Keywords

Cite

@article{arxiv.2109.13482,
  title  = {Charge Singlets and Orbital-Selective Charge Density Wave Transitions},
  author = {Yuxi Zhang and Chunhan Feng and Rubem Mondaini and George G. Batrouni and Richard T. Scalettar},
  journal= {arXiv preprint arXiv:2109.13482},
  year   = {2022}
}

Comments

10 pages, 11 figures

R2 v1 2026-06-24T06:25:02.471Z