Terahertz phonon engineering and spectroscopy with van der Waals heterostructures

Phononic engineering at GHz frequencies form the foundation of microwave acoustic filters, high-speed acousto-optic modulators, and quantum transducers. THz phononic engineering could lead to acoustic filters and modulators at higher bandwidth and speed, as well as quantum circuits operating at higher temperatures. It can also enable new ways to manipulate and control thermal transport, as THz acoustic phonons are the main heat carriers in nonmetallic solids. Despite its potential, methods for engineering THz phonons have been little explored due to the challenges of achieving the required material control at sub-nanometer precision and efficient phonon coupling at THz frequencies. Here, we demonstrate efficient generation, detection, and manipulation of THz phonons through precise integration of atomically thin layers in van der Waals heterostructures. We employ few-layer graphene as an ultrabroadband transducer, converting fs near-infrared pulses to broadband acoustic phonon pulses with spectral content up to 3 THz. A single layer of WSe$_2$ is used as a sensor, where high-fidelity readout is enabled by the exciton-phonon coupling and strong light-matter interactions. By combining these capabilities in a single van der Waals heterostructure and detecting responses to incident mechanical waves, we performed THz phononic spectroscopy, similar to conventional optical spectroscopy which detects responses to incident electromagnetic waves. We demonstrate high-Q THz phononic cavities using hBN stacks. We further show that a single layer of WSe$_2$ embedded in hBN can efficiently block the transmission of THz phonons. By comparing our measurements to a nanomechanical model, we obtain the important force constants at the heterointerfaces. Our results could enable THz phononic metamaterials based on van der Waals heterostructures, as well as novel routes for thermal engineering.