Discovery of acousto-drag photovoltaic effect

As a key ingredient in energy harvesting and photodetection, light-to-electricity conversion requires efficient separation of photoexcited electron-hole pairs before recombination. Traditional junction-based mechanisms mainly use build-in electric fields to achieve pair separation and generate photovoltaic effect, which fail to collect photoexcited pairs away from local barrier region. The ability to harvest photovoltaic effect in a homogeneous material upon uniform illumination is appealing, but has only been realized in very few cases such as non-centrosymmetric systems through bulk photovoltaic effect. Here we realize a new type of photovoltaic effect, termed as acousto-drag photovoltaic effect, by travelling surface acoustic waves (t-SAW) in a conventional layered semiconductor MoSe2. Instead of immediately driving the electron-hole pairs to opposite directions after generation, t-SAW induces periodic modulation to electronic bands and drags the photoexcited pairs toward the same travelling direction. The photocurrent can then be extracted by a local barrier, e.g. the metal-semiconductor contact as we used here. By spatially separating the electron-hole generation and extraction processes, the acousto-drag mechanism strongly suppresses charge recombination and yields large nonlocal photoresponse outside the barrier region. We show that when t-SAW is applied, the photoresponse can be enhanced by over two orders of magnitude with exceptionally high external quantum efficiency above 60 discovery of acousto-drag photovoltaic effect establishes a new approach towards efficient light-to-electricity conversion without the restriction of crystal symmetry.