Choosing WSe2 as a model system, we obtained a microscopic understanding of the nature of excited states in this prototypical transition metal dichalcogenide (TMDC) semiconductor. This includes the spin-, valley- and layer-polarisation of bright excitons, their binding energy as well as their interaction strength with the lattice, and the size of the exciton wavefunctions. The accompanying investigation of the lattice excitations generated by the interaction of the excitons with the atomic structure yields a comprehensive picture of the non-equilibrium states in TMDC materials.
We established FED as a methodology for investigating the flow of energy through electrons and vibrations in nanoscale heterostructures. In addition, we pioneer utilizing the inelastic scattering signal for retrieving momentum-resolved information of transient phonon distributions.
In parallel, we developed four-dimensional photoemission spectroscopy, which provides a view of the electronic structure resolved in energy, time and both momentum directions. Based on this, we established excited stated mapping as an extension of the band mapping concept with ARPES to excited / non-equilibrium states. The attached image shows a snapshot of the energy and momentum-distribution of excitons in WSe2 tens of femtosecond after the creation of the exciton with a short laser pulse.
A central aspect of this progress is the development of data analytics tools, which we share with the community.