The possibility of combining 2D materials in heterostructures allows the fabrication of new devices with novel functionalities, further expanding the opportunities of new science and new technologies. The properties of 2D crystals provide a unique platform to observe molecules under confinement, to artificially create new molecular phases and to exploit them to develop devices with new functionalities.
SPM techniques are the ideal tool for probing the properties of novel 2D nano-confined systems, in particular, the dielectric properties of nano-confined molecules, since they have a strong impact on many important physical phenomena. However, experimental evidence is lacking because dielectric measurements at such a small scale are technically challenging. To overcome this lack of experimental information, the overall objectives of this project were:
-Fabrication of 2D nanoenclosures/nanochannels that allow measurement of the dielectric properties of nanoconfined liquids with the scanning probe approach.
-Development of SPM tools/setups for in situ dielectric characterization of 2D nanoconfined liquids and chemical reactions under controlled conditions (temperature, liquid flow/concentration).
-Study of local electric polarization properties of 2D nanoconfined molecular fluids and their link to molecular organization (structure, phase) at solid interfaces by using the developed SPM tools.
We have developed and built new setups for the study of the dielectric properties of nanoconfined liquids, observing a decrease of the out-of-plane dielectric constant of confined water. Additionally, we studied the possible influence of topographic features and alignment in the electric and dielectric properties of 2D crystal devices.
In conclusion, the action has been successfully implemented by the unique combination of 2D materials-based confining structures with customized scanning probe tools for the characterization of liquids under extreme confinement at the nanoscale.