Transport in strained graphene: Interplay of Abelian and axial magnetic fields

TL;DR

This paper investigates how external magnetic and strain-induced axial fields in graphene influence electronic conductance and Hall effects, revealing new quantized plateaus and the emergence of charge-density-wave order.

Contribution

It numerically analyzes the combined effects of Abelian and axial magnetic fields on graphene's conductance and Hall conductivity, highlighting the formation of additional quantized plateaus and charge-density-wave states.

Findings

Quantized conductance plateaus at odd-integer multiples of e^2/h for flat graphene.

Strain-induced axial fields lift valley degeneracy, creating even-integer plateaus when B>b.

Charge-density-wave order induces a zero conductance and Hall plateau, with a staggered fermion density pattern.

Abstract

Immersed in external magnetic fields ($B$), buckled graphene constitutes an ideal tabletop setup, manifesting a confluence of time-reversal symmetry (${\mathcal T}$) breaking Abelian ($B$) and ${\mathcal T}$-preserving strain-induced internal axial ($b$) magnetic fields. In such a system, here we numerically compute two-terminal conductance ($G$), and four- as well as six-terminal Hall conductivity ($\sigma_{xy}$) for spinless fermions. On a flat graphene ($b=0$), the $B$ field produces quantized plateaus at $G=\pm |\sigma_{xy}|=(2n+1) e^2/h$, where $n=0,1,2, \cdots$. The strain induced $b$ field lifts the two-fold valley degeneracy of higher Landau levels and leads to the formation of additional even-integer plateaus at $G=\pm |\sigma_{xy}|= (2,4,\cdots)e^2/h$, when $B>b$. While the same sequence of plateaus is observed for $G$ when $b>B$, the numerical computation of $\sigma_{xy}$ in Hall bar geometries in this regime becomes unstable. A plateau at $G=\sigma_{xy}=0$ always appears with the onset of a charge-density-wave order, causing a staggered pattern of fermionic density between two sublattices of the honeycomb lattice.