In the first phase the project we have designed and realized the first waveguide for non-classical traveling mechanical excitations, which was published in Nature Physics. By fabricating the waveguide from thin film silicon we combine the waveguide with a source and detector for non-classical mechanical states, and we were able to verify the propagation of these quantum states in the waveguide. These acoustic waves at GHz frequencies are guided in a highly confined nanoscale geometries, with long lifetimes (up to several ms), in particular at low temperatures, enabling the faithful transport of quantum states over centimeter distances on a chip.
In the second phase of the project, we have demonstrated how such a waveguide can be used to distribute entangled states over a chip, which we then used to violate a Bell-type inequality, with the results published in Science Advances.