Attosecond control of collective electron motion in plasmas

Antonin Borot; Arnaud Malvache; Xiaowei Chen; Aurélie Jullien; Jean Paul Geindre; Patrick Audebert; Gérard Mourou; Fabien Quéré; Rodrigo Lopez-Martens

doi:10.1038/nphys2269

Attosecond control of collective electron motion in plasmas

Antonin Borot
, Arnaud Malvache
, Xiaowei Chen
, Aurélie Jullien
, Jean Paul Geindre
, Patrick Audebert
, Gérard Mourou
, Fabien Quéré
, Rodrigo Lopez-Martens

Research output: Contribution to journal › Article › peer-review

Abstract

Today, light fields of controlled and measured waveform can be used to guide electron motion in atoms and molecules with attosecond precision. Here, we demonstrate attosecond control of collective electron motion in plasmas driven by extreme intensity (≈10 ¹⁸cm ^-2) light fields. Controlled few-cycle near-infrared waves are tightly focused at the interface between vacuum and a solid-density plasma, where they launch and guide subcycle motion of electrons from the plasma with characteristic energies in the multi-kiloelectronvolt range-two orders of magnitude more than has been achieved so far in atoms and molecules. The basic spectroscopy of the coherent extreme ultraviolet radiation emerging from the light-plasma interaction allows us to probe this collective motion of charge with sub-200 as resolution. This is an important step towards attosecond control of charge dynamics in laser-driven plasma experiments.

Original language	English
Pages (from-to)	416-421
Number of pages	6
Journal	Nature Physics
Volume	8
Issue number	5
DOIs	https://doi.org/10.1038/nphys2269
Publication status	Published - 1 May 2012

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abstract = "Today, light fields of controlled and measured waveform can be used to guide electron motion in atoms and molecules with attosecond precision. Here, we demonstrate attosecond control of collective electron motion in plasmas driven by extreme intensity (≈10 18cm -2) light fields. Controlled few-cycle near-infrared waves are tightly focused at the interface between vacuum and a solid-density plasma, where they launch and guide subcycle motion of electrons from the plasma with characteristic energies in the multi-kiloelectronvolt range-two orders of magnitude more than has been achieved so far in atoms and molecules. The basic spectroscopy of the coherent extreme ultraviolet radiation emerging from the light-plasma interaction allows us to probe this collective motion of charge with sub-200 as resolution. This is an important step towards attosecond control of charge dynamics in laser-driven plasma experiments.",

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AU - Borot, Antonin

AU - Malvache, Arnaud

AU - Chen, Xiaowei

AU - Jullien, Aurélie

AU - Geindre, Jean Paul

AU - Audebert, Patrick

AU - Mourou, Gérard

AU - Quéré, Fabien

AU - Lopez-Martens, Rodrigo

PY - 2012/5/1

Y1 - 2012/5/1

N2 - Today, light fields of controlled and measured waveform can be used to guide electron motion in atoms and molecules with attosecond precision. Here, we demonstrate attosecond control of collective electron motion in plasmas driven by extreme intensity (≈10 18cm -2) light fields. Controlled few-cycle near-infrared waves are tightly focused at the interface between vacuum and a solid-density plasma, where they launch and guide subcycle motion of electrons from the plasma with characteristic energies in the multi-kiloelectronvolt range-two orders of magnitude more than has been achieved so far in atoms and molecules. The basic spectroscopy of the coherent extreme ultraviolet radiation emerging from the light-plasma interaction allows us to probe this collective motion of charge with sub-200 as resolution. This is an important step towards attosecond control of charge dynamics in laser-driven plasma experiments.

AB - Today, light fields of controlled and measured waveform can be used to guide electron motion in atoms and molecules with attosecond precision. Here, we demonstrate attosecond control of collective electron motion in plasmas driven by extreme intensity (≈10 18cm -2) light fields. Controlled few-cycle near-infrared waves are tightly focused at the interface between vacuum and a solid-density plasma, where they launch and guide subcycle motion of electrons from the plasma with characteristic energies in the multi-kiloelectronvolt range-two orders of magnitude more than has been achieved so far in atoms and molecules. The basic spectroscopy of the coherent extreme ultraviolet radiation emerging from the light-plasma interaction allows us to probe this collective motion of charge with sub-200 as resolution. This is an important step towards attosecond control of charge dynamics in laser-driven plasma experiments.

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DO - 10.1038/nphys2269

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JO - Nature Physics

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Attosecond control of collective electron motion in plasmas

Abstract

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