Exploring Novel Quantum Criticality in Strained Graphene
Abstract
Strain tuning is increasingly being recognized as a clean tuning parameter to induce novel behavior in quantum matter. Motivated by the possibility of straining graphene up to percent, we investigate novel quantum criticality due to interplay between strain-induced anisotropic band structure and critical antiferromagnetic spin fluctuations (AFSF) in this setting. We detail how this interplay drives a quantum phase transition (QPT) between the Dirac-semimetal-incoherent pseudogapped metal-correlated insulator as a function of strain (), and critical AFSF-driven divergent nematic susceptibility near critical strain () manifesting as critical singularities in magneto-thermal expansion and Gr\"uneisen co-efficients. The correlated band insulator at large strain affords realization of a two-dimensional dimerized spin-singlet state due to this interplay, and we argue how doping such an insulator can lead to a spin-charge separated metal, leading to anomalous metallicity and possible unconventional superconductivity. On a wider front, our work serves to illustrate the range of novel states realizable by strain-tuning quantum materials.
Cite
@article{arxiv.1611.04518,
title = {Exploring Novel Quantum Criticality in Strained Graphene},
author = {S. Arya and M. S. Laad and S. R. Hassan},
journal= {arXiv preprint arXiv:1611.04518},
year = {2017}
}
Comments
5 pages of main text and 9 pages of suppl. information