Femtosecond x rays from laser-plasma accelerators

Corde, S.; Phuoc, K. Ta; Lambert, Guillaume; Fitour, R.; Malka, Victor; Rousse, A.; Beck, Arnaud; Lefebvre, E.

doi:10.1103/revmodphys.85.1

Cited by 677 publications

(579 citation statements)

References 276 publications

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“…Studies of time-resolved electron dynamics in various atomic, molecular, and condensed-matter reactions have increased over the past two decades [1][2][3][4][5][6][7] owing to experimental progress in generating ultrashort and/or intense pulses of extreme ultraviolet light [8,9], x rays [10,11], and electrons [12,13]. These advances open the possibility of obtaining a deeper understanding of physical and chemical reaction mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Time-resolved electron(e,2e)momentum spectroscopy: Application to laser-driven electron population transfer in atoms

Shao

Starace

2018

Phys. Rev. A

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Owing to its ability to provide unique information on electron dynamics, time-resolved electron momentum spectroscopy (EMS) is used to study theoretically a laser-driven electronic motion in atoms. Specifically, a chirped laser pulse is used to adiabatically transfer the populations of lithium atoms from the ground state to the first excited state. During this process, impact ionization near the Bethe ridge by time-delayed ultrashort, high-energy electron pulses is used to image the instantaneous momentum density of this electronic population transfer. Simulations with 100 fs and 1 fs pulse durations demonstrate the capability of EMS to image the time-varying momentum density, including its change of symmetry as the population transfer progresses. Moreover, the spectra corresponding to different pulse durations reveal different kinds of electronic motion. We discuss how to properly interpret these time-resolved EMS spectra, which represent a generalization of time-independent EMS.

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Section: Introductionmentioning

confidence: 99%

Time-resolved electron(e,2e)momentum spectroscopy: Application to laser-driven electron population transfer in atoms

Shao

Starace

2018

Phys. Rev. A

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“…The expeled electrons are further accelerated by the laser, and re-injected into the bulk material once the electric field changes its direction. In this process deep ultraviolet (VUV), extreme ultraviolet (XUV), and X-ray radiation are generated (see for example [1][2][3] and references therein). For intensities of 10 18 Wcm −2 not only electrons are accelerated but also protons, and if the laser intensity increases to 10 20 Wcm −2 there are mechanisms for the acceleration of neutrons (see [4,5] and references therein).…”

Section: Introductionmentioning

confidence: 99%

Laser-based X-ray and electron source for X-ray fluorescence studies

Brozas¹,

Crego

Roso³

et al. 2016

Appl. Phys. B

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In this work we present a modification to conventional X-rays fluorescence using electrons as excitation source, and compare it with the traditional X-ray excitation for the study of pigments. For this purpose we have constructed a laser-based source capable to produce X-rays as well as electrons. Because of the large penetration depth of X-rays, the collected fluorescence signal is a combination of several material layers of the artwork under study. However electrons are stopped in the first layers allowing therefore a more superficial analysis. We show that the combination of both excitation sources can provide extremely valuable information about the structure of the artwork.

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“…A laser wakefield accelerator [7] has been proven useful to generate 10-50 fs electron bunches. It is envisaged that a future dielectric laser accelerator (DLA) [8], directly driven by a laser field, is to generate electron bunches in the attosecond time scale.…”

Section: Introductionmentioning

confidence: 99%

Isolated few-cycle radiation from chirped-pulse compression of a superradiant free-electron laser

Huang

Zhang

Chen

et al. 2015

Phys. Rev. ST Accel. Beams

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When a short electron bunch traverses an undulator to radiate a wavelength longer than the bunch length, intense superradiance from the electron bunch can quickly deplete the electron's kinetic energy and lead to generation of an isolated chirped radiation pulse. Here, we develop a theory to describe this novel chirped pulse radiation in a superradiant free-electron laser and show the opportunity to generate isolated few-cycle high-power radiation through chirped-pulse compression after the undulator. The theory is completely characterized by how fast the electron energy is depleted for a given length of an undulator. We further present two design examples at the THz and extreme-ultraviolet wavelengths and numerically generate isolated three-and nine-cycle radiation pulses, respectively.

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Femtosecond x rays from laser-plasma accelerators

Cited by 677 publications

References 276 publications

Time-resolved electron(e,2e)momentum spectroscopy: Application to laser-driven electron population transfer in atoms

Time-resolved electron(e,2e)momentum spectroscopy: Application to laser-driven electron population transfer in atoms

Laser-based X-ray and electron source for X-ray fluorescence studies

Isolated few-cycle radiation from chirped-pulse compression of a superradiant free-electron laser

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