Torsional Hall Viscosity of Massive Chern Insulators: Magnetic Field and Momentum Deformations

This work focuses on the non-dissipative, parity-odd spin transport of (2 + 1)-dimensional relativistic electrons, generated by torsion, and the torsional Hall viscosity $\zeta_{\mathrm{H}}$. We first determine $\zeta_{\mathrm{H}}$ for massive Dirac fermions in the presence of a constant electromagnetic field. We predict that the magnetic field induces a contribution to $\zeta_{\mathrm{H}}$ competing with the one originating from the Dirac mass. Moreover, we quantify the impact on $\zeta_{\mathrm{H}}$ originating from the band structure deformation quadratic in momentum terms that was proposed by Bernevig-Hughes-Zhang (BHZ). We find that the BHZ deformation enhances $\zeta_{\mathrm{H}}$ in magnitude, but reverses its sign as compared to the standard massive Dirac fermion, indicating a Hall response in opposite direction to the typical Hall viscous force. Nevertheless, the torsional Hall viscosity still discriminates between topologically trivial and non-trivial regimes. Our results, hence, pave the way for a deeper understanding of hydrodynamic spin transport and its possible verification in experiments.