Colossal Photovoltaic Effect Driven by the Singular Berry Curvature in a Weyl Semimetal

The non-trivial evolution of wavefunctions in momentum space leads to novel phases and responses. As with any topological property, a key challenge lies in finding experiments that identify the non-local characteristics. Indeed, revealing this Berry curvature often requires extreme conditions and/or surface sensitive probes. These rely on measuring the Berry phase acquired through a closed loop evolution in momentum space, or through the bulk-boundary correspondence leading to new states at the surface. Alternatively, various components of the electronic structure can be detected by the bulk photovoltaic effect (BPVE) where non-linearity rectifies light to dc currents. Weyl semimetals are particularly promising, as their non-degenerate, Dirac-like, chiral states produce diverging Berry curvature. Here we report a room temperature, colossal BPVE in the Weyl semimetal TaAs, which is an order of magnitude larger than any previous measurement. By varying the polarization of light with respect to the crystal axis, we establish the collosal BPVE resulting from the non-trivial topology of Weyl fermions, i.e. the diverging Berry curvature near the Weyl nodes. The BPVE in Weyl semiemtals we uncover can be exploited for detecting electron topology, broadband detectors, and solar/thermal energy conversion.