Quantum geometry (Berry curvature and quantum metric) determines both Hall viscosity and the quadratic term in nonlocal Hall conductivity in lattice bands via a projected electric quadrupole.
Lorentz shear modulus of fractional quantum Hall states
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
We show that the Lorentz shear modulus of macroscopically homogeneous electronic states in the lowest Landau level is proportional to the bulk modulus of an equivalent system of interacting classical particles in the thermodynamic limit. Making use of this correspondence we calculate the Lorentz shear modulus of Laughlin's fractional quantum Hall states at filling factor $\nu=1/m$ ($m$ an odd integer) and find that it is equal to $\pm \hbar mn/4$, where $n$ is the density of particles and the sign depends on the direction of magnetic field. This is in agreement with the recent result obtained by Read in arXiv:0805.2507 and corrects our previous result published in Phys. Rev. B {\bf 76}, 161305 (R) (2007).
fields
cond-mat.mes-hall 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
-
Quantum Geometric Origin of Hall Viscosity and Nonlocal Hall Conductivity in Lattice Bands
Quantum geometry (Berry curvature and quantum metric) determines both Hall viscosity and the quadratic term in nonlocal Hall conductivity in lattice bands via a projected electric quadrupole.