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  Rossi, T.C.; Qiao, L.; Dykstra, C.P.; Rodrigues Pela, R.; Gnewkow, R.; Wallick, R.F.; Burke, J.H.; Nicholas, E.; March, A.M.; Doumy, G.; Buchholz, D.B.; Deparis, C.; Zúñiga-Pérez, J.; Weise, M.; Ellmer, K.; Fondell, M.; Draxl, C.; van der Veen, R.M.: Dynamic control of X-ray core-exciton resonances by Coulomb screening in photoexcited semiconductors. Communications Materials 6 (2025)

10.1038/s43246-025-00909-w
Open Accesn Version

Abstract:
Excitonics is an emerging field focused on exploiting and manipulating excitons generated through light-matter interactions. Advancing the field into X-ray excitonics requires precise energy and time control of core-exciton resonances, enabling non-linear X-ray phenomena such as element-specific X-ray transient gratings, and advancing material characterization. To achieve these objectives, it is essential to comprehend the role of many-body effects governing core-exciton dynamics. In this work, we address this challenge by combining experiments with an ab initio approach specifically developed to interpret pump-probe excitations. Applied to the prototypical wide-bandgap semiconductor ZnO, first-principles calculations reproduce experimental results and unveil how the density and distribution of photoexcited carriers dynamically tune Coulomb screening, thereby controlling core-exciton binding energies, while Pauli blocking remains negligible. These insights inform a method for dynamically controlling core-exciton resonances at absorption edges, achieving either a uniform spectral blue shift caused by thermalized carrier distributions on picosecond timescales, or distinct blue shifts for individual resonances, driven by time-dependent carrier distributions on femtosecond timescales.