Sub-cycle quantum electrodynamics in strongly laser-driven semiconductors
Abstract
Electrodynamical processes induced in complex systems like semiconductors by strong electromagnetic fields, have traditionally/conventionally been described using semi-classical approaches. Although these approaches, allowed the investigation of ultrafast dynamics in solids culminating in multi-petahertz electronics, they do not provide any access in the quantum optical nature of the interaction as they treat the driving-field classically and unaffected by the interaction. Here, using a full quantum-optical approach, we demonstrate that the sub-cycle electronic response in a strongly driven semiconductor crystal is imprinted in the quantum-state of the driving-field resulting in non-classical light-states carrying the information of the interaction. This vital step towards strong-field ultrafast quantum electrodynamics unravels information inaccessible by conventional approaches and leads to the development of a new class non-classical light sources.
Cite
@article{arxiv.1810.12721,
title = {Sub-cycle quantum electrodynamics in strongly laser-driven semiconductors},
author = {N. Tsatrafyllis and S. Kuhn and M. Dumergue and P. Foldi and S. Kahaly and E. Cormier and I. A. Gonoskov and B. Kiss and K. Varju and S. Varro and P. Tzallas},
journal= {arXiv preprint arXiv:1810.12721},
year = {2019}
}
Comments
24 pages, 9 figures