C. Filip scite author profile

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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Temporal Characterization of Femtosecond Laser-Plasma-Accelerated Electron Bunches Using Terahertz Radiation

Tilborg

et al. 2006

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The temporal profile of relativistic laser-plasma-accelerated electron bunches has been characterized. Coherent transition radiation at THz frequencies, emitted at the plasma-vacuum boundary, was measured through electro-optic sampling. Frequencies up to the crystal detection limit of 4 THz were observed. Comparison between data and theory indicates that THz radiation from bunches with structure shorter than approximately = 50 fs (root-mean-square) is emitted. The measurement demonstrates both shot-to-shot stability of the laser-plasma accelerator and femtosecond synchronization between bunch and probe beam.

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Terahertz radiation as a bunch diagnostic for laser-wakefield-accelerated electron bunches

Tilborg

Schroeder

Filip

et al. 2006

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Experimental results are reported from two measurement techniques ͑semiconductor switching and electro-optic sampling͒ that allow temporal characterization of electron bunches produced by a laser-driven plasma-based accelerator. As femtosecond electron bunches exit the plasma-vacuum interface, coherent transition radiation ͑at THz frequencies͒ is emitted. Measuring the properties of this radiation allows characterization of the electron bunches. Theoretical work on the emission mechanism is presented, including a model that calculates the THz wave form from a given bunch profile. It is found that the spectrum of the THz pulse is coherent up to the 200 m thick crystal ͑ZnTe͒ detection limit of 4 THz, which corresponds to the production of sub-50 fs ͑rms͒ electron bunch structure. The measurements demonstrate both the shot-to-shot stability of bunch parameters that are critical to THz emission ͑such as total charge and bunch length͒, as well as femtosecond synchronization among bunch, THz pulse, and laser beam.

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Enhanced Acceleration of Injected Electrons in a Laser-Beat-Wave-Induced Plasma Channel

et al. 2004

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Enhanced energy gain of externally injected electrons by a approximately 3 cm long, high-gradient relativistic plasma wave (RPW) is demonstrated. Using a CO2 laser beat wave of duration longer than the ion motion time across the laser spot size, a laser self-guiding process is initiated in a plasma channel. Guiding compensates for ionization-induced defocusing (IID) creating a longer plasma, which extends the interaction length between electrons and the RPW. In contrast to a maximum energy gain of 10 MeV when IID is dominant, the electrons gain up to 38 MeV energy in a laser-beat-wave-induced plasma channel.

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Optical Kerr switching technique for the production of a picosecond, multiwavelength CO_2 laser pulse

Filip¹,

Narang²,

Tochitsky³

et al. 2002

Appl. Opt.

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C. Filip

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

Temporal Characterization of Femtosecond Laser-Plasma-Accelerated Electron Bunches Using Terahertz Radiation

Terahertz radiation as a bunch diagnostic for laser-wakefield-accelerated electron bunches

Enhanced Acceleration of Injected Electrons in a Laser-Beat-Wave-Induced Plasma Channel

Optical Kerr switching technique for the production of a picosecond, multiwavelength CO_2 laser pulse

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