Add to ORKGWe show that the emergent relativistic symmetry of electrons in graphene near its quantum critical point (QCP) implies a crucial importance of the Coulomb interaction. We derive scaling laws, valid near the QCP, that dictate the nontrivial magnetic and charge response of interacting graphene. Our analysis yields numerous predictions for how the Coulomb interaction will be manifested in experimental observables such as the diamagnetic response and electronic compressibility. © 2007 The American Physical Society
We study the thermal and electric transport of a fluid of interacting Dirac fermions as they arise i...
Insights into the fundamental properties of graphene’s Dirac-Weyl fermions have emerged from studies...
Monte Carlo simulation of a 2+1 dimensional model of voltage-biased bilayer graphene, consisting of ...
In this paper, we consider the possibility of chiral (charge or spin density wave) symmetry breaking...
We analyze by exact Renormalization Group (RG) methods the infrared properties of an effective model...
The low-energy theory of graphene exhibits spontaneous chiral symmetry breaking due to pairing of qu...
We study the presence of ferromagnetism in the phase diagram of the two-dimensional honeycomb latti...
We study the presence of ferromagnetism in the phase diagram of the two-dimensional honeycomb latti...
Shytov, Andrei et al. “Atomic collapse, Lorentz boosts, Klein scattering, and other quantum-relativi...
A new effect in graphene in the presence of crossed uniform electric and magnetic fields is predicte...
We present the first results of numerical simulations of a 2+1 dimensional fermion field theory base...
We explore the renormalization group flow of quartic perturbations in the low-enegy theory of graphe...
Optical conductivity of graphene is studied using quantum Monte Carlo calculations. We start from a ...
Journal ArticleMinimal conductivity of a single undoped graphene layer is known to be of the order o...
The impact of the electron-electron Coulomb interaction on the optical conductivity of graphene has ...
We study the thermal and electric transport of a fluid of interacting Dirac fermions as they arise i...
Insights into the fundamental properties of graphene’s Dirac-Weyl fermions have emerged from studies...
Monte Carlo simulation of a 2+1 dimensional model of voltage-biased bilayer graphene, consisting of ...
In this paper, we consider the possibility of chiral (charge or spin density wave) symmetry breaking...
We analyze by exact Renormalization Group (RG) methods the infrared properties of an effective model...
The low-energy theory of graphene exhibits spontaneous chiral symmetry breaking due to pairing of qu...
We study the presence of ferromagnetism in the phase diagram of the two-dimensional honeycomb latti...
We study the presence of ferromagnetism in the phase diagram of the two-dimensional honeycomb latti...
Shytov, Andrei et al. “Atomic collapse, Lorentz boosts, Klein scattering, and other quantum-relativi...
A new effect in graphene in the presence of crossed uniform electric and magnetic fields is predicte...
We present the first results of numerical simulations of a 2+1 dimensional fermion field theory base...
We explore the renormalization group flow of quartic perturbations in the low-enegy theory of graphe...
Optical conductivity of graphene is studied using quantum Monte Carlo calculations. We start from a ...
Journal ArticleMinimal conductivity of a single undoped graphene layer is known to be of the order o...
The impact of the electron-electron Coulomb interaction on the optical conductivity of graphene has ...
We study the thermal and electric transport of a fluid of interacting Dirac fermions as they arise i...
Insights into the fundamental properties of graphene’s Dirac-Weyl fermions have emerged from studies...
Monte Carlo simulation of a 2+1 dimensional model of voltage-biased bilayer graphene, consisting of ...