Michael Sentef1,2
University of Bremen1,MPSD Hamburg2
Michael Sentef1,2
University of Bremen1,MPSD Hamburg2
Advances in time-resolved pump-probe spectroscopies have enabled us to follow the microscopic dynamics of quantum materials on femtosecond time scales. This gives us a glimpse into the inner workings of how complex, emergent functionalities of quantum many-body systems develop on ultrafast time scales or react to external forces. The ultimate dream of the community is to use light as a tuning parameter to create new states of matter on demand with designed properties and new functionalities, perhaps not achievable by other means. In this talk I will discuss recent progress in controlling and engineering properties of quantum materials through light-matter interaction [a,b]. I will highlight work on Floquet engineering — the creation of effective Hamiltonians by time-periodic drives — on sub-cycle time scales [1,2] combining theory and pump-probe experiments at the limits of energy and time resolution. I will then showcase recent theories on inducing superconductivity with light by employing enhanced light-matter interaction in the near-field involving polaritonic excitations [3,4]. <br/><br/>[a] A. de la Torre et al., Rev. Mod Phys. 93, 041002 (2021)<br/>[b] F. Schlawin, D. M. Kennes, M. A. Sentef, App. Phys. Rev. 9, 011312 (2022)<br/>[1] M. Schüler and M. A. Sentef, https://doi.org/10.1016/j.elspec.2021.147121<br/>[2] S. Ito et al., Nature 616, 696-701 (2023), https://www.nature.com/articles/s41586-023-05850-x<br/>[3] C. J. Eckhardt et al., arXiv:2303.02176<br/>[4] S. Chattopadhyay et al., arXiv:2303.15355