Ballistic magnetotransport and field-induced interaction effects in graphene

Ballistic magnetotransport and field-induced interaction effects in graphene
Prof. Tigran Sedrakyan, Physics Department, UMass Amherst
Tigran Sedrakyan image
Date and time: Thu, Oct 21, 2021 - 11:30am
Location: LGRT 1033
Category: Condensed Matter Seminar
Abstract:

A weak perpendicular magnetic field, B, breaks the chiral symmetry of each valley in the electron spectrum of graphene, preserving the overall chiral symmetry in the Brillouin zone. We explore the consequences of this symmetry breaking for the interaction effects in graphene. In particular, we demonstrate that: 1) the electron-electron interaction lifetime acquires an anomalous B-dependence. Also, the ballistic zero-bias anomaly emerges at a weak B that has an algebraic form. 2) The perpendicular magnetic field introduces an anomalous interaction correction to the static conductivity of doped graphene in the ballistic regime. The correction implies that the magnetoresistance scales inversely with temperature ∝ 1/T in a parametrically large interval. When the disorder is scalar-like, the ∝ 1/T behavior is the leading contribution in the crossover between diffusive regime exhibiting weak localization and quantum magnetooscillations. 3) Temperature dependence of the magnetic-field corrections to the thermodynamic characteristics of graphene is also anomalous.
We discuss experimental manifestations of the predicted effects.