Controlling attosecond electron dynamics by phase-stabilized polarization gating
Author: ["I. J. Sola","E. Mével","L. Elouga","E. Constant","V. Strelkov","L. Poletto","P. Villoresi","E. Benedetti","J.-P. Caumes","S. Stagira","C. Vozzi","G. Sansone","M. Nisoli"]
Publication: Nature Physics
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Abstract
Attosecond electron wavepackets are produced when an intense laser field ionizes an atom or a molecule1. When the laser field drives the wavepackets back to the parent ion, they interfere with the bound wavefunction, producing coherent subfemtosecond extreme-ultraviolet light bursts. When only a single return is possible2,3, an isolated attosecond pulse is generated. Here we demonstrate that by modulating the polarization of a carrier-envelope phase-stabilized short laser pulse4, we can finely control the electron-wavepacket dynamics. We use high-order harmonic generation to probe these dynamics. Under optimized conditions, we observe the signature of a single return of the electron wavepacket over a large range of energies. This temporally confines the extreme-ultraviolet emission to an isolated attosecond pulse with a broad and tunable bandwidth. Our approach is very general, and extends the bandwidth of attosecond isolated pulses in such a way that pulses of a few attoseconds seem achievable. Similar temporal resolution could also be achieved by directly using the broadband electron wavepacket. This opens up a new regime for time-resolved tomography of atomic or molecular wavefunctions5,6 and ultrafast dynamics.
Cite this article
Sola, I., Mével, E., Elouga, L. et al. Controlling attosecond electron dynamics by phase-stabilized polarization gating. Nature Phys 2, 319–322 (2006). https://doi.org/10.1038/nphys281
