The power to control phonons, which are quantized lattice vibrations responsible for the transmission of sound and heat, would lead to extraordinary technological developments in thermal applications. Phonons play a crucial role in solid-state physics also in the interaction with electrons and photons. Therefore, the need to understand and control phonons arises also from optoelectronic and electronic applications, where interaction with phonons is often the bottleneck of device performances.
The controlled modification of phonon dispersion, interactions, and transport define the concept of phonon engineering, which allows controlling heat propagation and tuning electron-phonon and photon-phonon interactions. The combination of phonon engineering and nanostructuring defines the nanophononics field and is one of the most promising routes for thermal management. In this context, new theoretical and experimental methods are required.
With PHONUIT, we tackle the challenges of nanophononics both from the materials point of view, i.e. engineering the phononic properties of nanostructures, as well as from the methodology point of view, i.e. pushing the limits of currently existing experimental methods and developing novel measurements methods and platforms. Specifically, this project aims to realize a phononic integrated circuit, where phonons in coherent and/or incoherent form are generated, routed and detected on chip.