Spin conductance and spin conductivity in topological insulators: analysis of Kubo-like terms
We investigate spin transport in $2$-dimensional insulators, with the long-term goal of establishing whether any of the transport coefficients corresponds to the Fu-Kane-Mele index which characterizes $2d$ time-reversal-symmetric topological insulators.
Inspired by the Kubo theory of charge transport, and by using a proper definition of the
spin current operator \cite{ShiZhangXiaoNiu}, we define the Kubo-like spin conductance $G_K^{s_z}$ and spin conductivity $\sigma_K^{s_z}$.
We prove that for any gapped, periodic, near-sighted discrete Hamiltonian, the above quantities are mathematically well-defined and the equality $G_K^{s_z} = \sigma_K^{s_z}$ holds true.
Moreover, we argue that the physically relevant condition to obtain the equality above is the vanishing of the mesoscopic average of the spin-torque response, which holds true under our hypotheses on the Hamiltonian operator.
A central role in the proof is played by the trace per unit volume and by two generalizations of the trace,
the \emph{principal value trace} and its directional version.