A topological principle for photovoltaics: Shift current in intrinsically polar insulators

To realize an efficient solar cell without inhomogeneous doping, one would like to maximize the shift component of the bulk photovoltaic current, in noncentric semiconductors with wide band gaps. I achieve this maximization for a new class of topological insulators whose band topology is only compatible with a polar crystal class. For such insulators, it is impossible to continuously tune the $\boldsymbol{k}$-dependent electron-hole dipole moment (or `shift vector') to zero throughout the Brillouin zone. Averaging the shift vector over all high-symmetry cross-sections of the Brillouin zone gives exactly a rational multiple of a Bravais lattice vector, which points parallel to the polar axis. Even with wide band gaps, the frequency-integrated shift conductivity of intrinsically polar insulators greatly exceeds $e^3/h^2$, and is at least three orders of magnitude larger than the conductivity of the prototypical ferroelectric BaTiO$_3$, challenging a widely-held expectation that small band gaps are necessary for large shift currents in topological materials. Close to a topological phase transition, the integrated conductivity diverges as $|E_g|^{-1/2}$ with $E_g$ the band gap, suggesting an application to ultrafast infrared detection.