Ultrafast dynamics and light-induced superconductivity from first principles
Abstract
Experiments on superconducting materials have unveiled unique emergent properties when they are driven far from equilibrium. However, a quantitative first-principles treatment that describes experimental observations is lacking. In this work, we develop an ab-initio model for the nonequilibrium response of optically irradiated superconducting films within the framework of conventional electron-phonon-mediated superconductivity, leveraging new numerical techniques to solve the Migdal-Eliashberg equations directly on the real-frequency axis. This enables us to quantitatively reproduce the optical response of superconducting films in pump-probe experiments and validate our approach on measurements of the differential reflectance of Pb and LaH in response to a pump excitation. Similar calculations performed on the alkali-doped fulleride KC reveal that a photo-induced superconducting state is generated after irradiation by an ultrafast mid-infrared pulse of sufficient intensity, as reported in prior experimental work. The enhancement in this framework is attributed to the excitation of quasiparticles to energies resonant with the strongest electron-phonon coupling in KC, in close analogy to the mechanism for enhancement of superconductivity under microwave irradiation, explaining the nature of the photo-induced superconducting state and elucidating the subsequent quasiparticle and phonon dynamics. Our results suggest that photo-induced superconductivity is accessible in more materials than previously recognized. We demonstrate this by performing calculations on calcium-intercalated graphite, CaC, and predict a similar photo-induced superconducting gap.
Cite
@article{arxiv.2603.18182,
title = {Ultrafast dynamics and light-induced superconductivity from first principles},
author = {Alejandro Simon and James Shi and Eva Kogler and Reed Foster and Dominik Spath and Emma Batson and Pedro N. Ferreira and Mihir Sahoo and Rohit Prasankumar and Phillip D. Keathley and Karl K. Berggren and Christoph Heil},
journal= {arXiv preprint arXiv:2603.18182},
year = {2026}
}
Comments
15 pages, 11 figures