Real-time reconstruction of complex non-equilibrium quantum dynamics of matter
Veit Stoo{\ss}, Stefano M. Cavaletto, Alexander Bl\"attermann, Paul, Birk, Christoph H. Keitel, Christian Ott, Thomas Pfeifer

TL;DR
This paper presents a method to reconstruct the full time-dependent response of strongly driven, non-equilibrium quantum systems from a single absorption spectrum, enabling real-time analysis down to attoseconds without scanning delays.
Contribution
It introduces a novel approach for single-shot, real-time reconstruction of quantum dynamics from a single short signal, applicable to arbitrary interactions and out-of-equilibrium states.
Findings
Successfully reconstructed Rabi cycling in atomic states within femtoseconds.
Achieved real-time response retrieval down to attoseconds.
Eliminated the need for delay scanning in ultrafast spectroscopy.
Abstract
Causality implies that by measuring an absorption spectrum, the time-dependent linear response function can be retrieved. Recent experiments suggest a link between the shape of spectral lines observed in absorption spectroscopy with the amplitude and phase of the systems response function. This has even been observed in the presence of strong, nonlinear interactions, which promote the observed system out of equilibrium, making it explicitly time dependent. Thus far, however, only the special case of a sudden modification of the response function was understood analytically, leaving the general case of the dynamical response to arbitrary interactions open to interpretation. Here, we demonstrate that even for the case of a strongly driven, time-dependent system, one can reconstruct the full temporal response information from a single spectrum if a sufficiently short signal is used to…
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Taxonomy
TopicsAtomic and Subatomic Physics Research · Cold Atom Physics and Bose-Einstein Condensates · Quantum Mechanics and Applications
