Time-resolved photoemission using attosecond streaking
Abstract
We theoretically study time-resolved photoemission in atoms as probed by attosecond streaking. We review recent advances in the study of the photoelectric effect in the time domain and show that the experimentally accessible time shifts can be decomposed into distinct contributions that stem from the field-free photoionization process itself and from probe-field induced corrections. We perform accurate quantum-mechanical as well as classical simulations of attosecond streaking for effective one-electron systems and determine all relevant contributions to the time delay with attosecond precision. In particular, we investigate the properties and limitations of attosecond streaking for the transition from short-ranged potentials (photodetachment) to long-ranged Coulomb potentials (photoionization). As an example for a more complex system, we study time-resolved photoionization for endohedral fullerenes @ and discuss how streaking time shifts are modified due to the interaction of the cage with the probing infrared streaking field.
Cite
@article{arxiv.1401.6328,
title = {Time-resolved photoemission using attosecond streaking},
author = {Stefan Nagele and Renate Pazourek and Michael Wais and Georg Wachter and Joachim Burgdörfer},
journal= {arXiv preprint arXiv:1401.6328},
year = {2015}
}
Comments
Submitted to J.Phys.Conf.Ser. (ICPEAC 2013 conference proceedings) on 27.09.2013, accepted on 28.10.2013, final version submitted on 15.11.2013