F. Albert scite author profile

Since the invention of the laser more than 50 years ago, scientists have striven to achieve amplification on atomic transitions of increasingly shorter wavelength. The introduction of X-ray free-electron lasers makes it possible to pump new atomic X-ray lasers with ultrashort pulse duration, extreme spectral brightness and full temporal coherence. Here we describe the implementation of an X-ray laser in the kiloelectronvolt energy regime, based on atomic population inversion and driven by rapid K-shell photo-ionization using pulses from an X-ray free-electron laser. We established a population inversion of the Kα transition in singly ionized neon at 1.46 nanometres (corresponding to a photon energy of 849 electronvolts) in an elongated plasma column created by irradiation of a gas medium. We observed strong amplified spontaneous emission from the end of the excited plasma. This resulted in femtosecond-duration, high-intensity X-ray pulses of much shorter wavelength and greater brilliance than achieved with previous atomic X-ray lasers. Moreover, this scheme provides greatly increased wavelength stability, monochromaticity and improved temporal coherence by comparison with present-day X-ray free-electron lasers. The atomic X-ray lasers realized here may be useful for high-resolution spectroscopy and nonlinear X-ray studies.

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Self-Guided Laser Wakefield Acceleration beyond 1 GeV Using Ionization-Induced Injection

Clayton

et al. 2010

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Demonstration of a Narrow Energy Spread,∼0.5 GeVElectron Beam from a Two-Stage Laser Wakefield Accelerator

et al. 2011

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Laser wakefield acceleration of electrons holds great promise for producing ultracompact stages of GeV scale, high-quality electron beams for applications such as x-ray free electron lasers and high-energy colliders. Ultrahigh intensity laser pulses can be self-guided by relativistic plasma waves (the wake) over tens of vacuum diffraction lengths, to give >1 GeV energy in centimeter-scale low density plasmas using ionization-induced injection to inject charge into the wake even at low densities. By restricting electron injection to a distinct short region, the injector stage, energetic electron beams (of the order of 100 MeV) with a relatively large energy spread are generated. Some of these electrons are then further accelerated by a second, longer accelerator stage, which increases their energy to ∼0.5 GeV while reducing the relative energy spread to <5% FWHM.

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Imaging Electron Trajectories in a Laser-Wakefield Cavity Using Betatron X-Ray Radiation

et al. 2006

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Laser wakefield accelerator based light sources: potential applications and requirements

Albert¹,

Thomas²,

Mangles³

et al. 2014

Plasma Phys. Control. Fusion

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In this article we review the prospects of laser wakefield accelerators as next generation light sources for applications. This work arose as a result of discussions held at the 2013 Laser Plasma Accelerators Workshop. X-ray phase contrast imaging, x-ray absorption spectroscopy, and nuclear resonance fluorescence are highlighted as potential applications for laser-plasma based light sources. We discuss ongoing and future efforts to improve the properties of radiation from plasma betatron emission and Compton scattering using laser wakefield accelerators for these specific applications.

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2020 roadmap on plasma accelerators

et al. 2021

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Plasma-based accelerators use the strong electromagnetic fields that can be supported by plasmas to accelerate charged particles to high energies. Accelerating field structures in plasma can be generated by powerful laser pulses or charged particle beams. This research field has recently transitioned from involving a few small-scale efforts to the development of national and international networks of scientists supported by substantial investment in large-scale research infrastructure. In this New Journal of Physics 2020 Plasma Accelerator Roadmap, perspectives from experts in this field provide a summary overview of the field and insights into the research needs and developments for an international audience of scientists, including graduate students and researchers entering the field.

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Inertially confined fusion plasmas dominated by alpha-particle self-heating

et al. 2016

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Angular Dependence of Betatron X-Ray Spectra from a Laser-Wakefield Accelerator

et al. 2013

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We present the first measurements of the angular dependence of the betatron x-ray spectrum produced by electrons inside the cavity of a laser-wakefield accelerator. Electrons accelerated up to 300 MeV energies produce a beam of broadband, forward-directed betatron x-ray radiation extending up to 80 keV. The angular resolved spectrum from an image plate-based spectrometer with differential filtering provides data in a single laser shot. The simultaneous spectral and spatial x-ray analysis allows for a three-dimensional reconstruction of electron trajectories with micrometer resolution, and we find that the angular dependence of the x-ray spectrum is showing strong evidence of anisotropic electron trajectories.

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F. Albert

Atomic inner-shell X-ray laser at 1.46 nanometres pumped by an X-ray free-electron laser

Self-Guided Laser Wakefield Acceleration beyond 1 GeV Using Ionization-Induced Injection

Demonstration of a Narrow Energy Spread,∼0.5 GeVElectron Beam from a Two-Stage Laser Wakefield Accelerator

Imaging Electron Trajectories in a Laser-Wakefield Cavity Using Betatron X-Ray Radiation

Laser wakefield accelerator based light sources: potential applications and requirements

2020 roadmap on plasma accelerators

Inertially confined fusion plasmas dominated by alpha-particle self-heating

Angular Dependence of Betatron X-Ray Spectra from a Laser-Wakefield Accelerator

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