论文信息 - Electron Acceleration by a Wake Field Forced by an Intense Ultrashort Laser Pulse - 字舞流文

Electron Acceleration by a Wake Field Forced by an Intense Ultrashort Laser Pulse

Plasmas are an attractive medium for the next generation of particle accelerators because they can support electric fields greater than several hundred gigavolts per meter. These accelerating fields are generated by relativistic plasma waves—space-charge oscillations—that can be excited when a high-intensity laser propagates through a plasma. Large currents of background electrons can then be trapped and subsequently accelerated by these relativistic waves. In the forced laser wake field regime, where the laser pulse length is of the order of the plasma wavelength, we show that a gain in maximum electron energy of up to 200 megaelectronvolts can be achieved, along with an improvement in the quality of the ultrashort electron beam.

G. Malka | S. Fritzler | M. Pittman | A. E. Dangor | Z. Najmudin | S. P. D. Mangles | V. Malka | K. Krushelnick | F. Burgy | A. Dangor | V. Malka | E. Lefebvre | K. Krushelnick | J.-P. Chambaret | G. Malka | E. Lefebvre | J.-P. Rousseau | S. Mangles | Z. Najmudin | B. Walton | J. Chambaret | M. Pittman | J. Rousseau | F. Burgy | S. Fritzler | M. Aleonard | J. Chemin | J. Scheurer | B. Walton | M.-M. Aleonard | J.-F. Chemin | J.-N. Scheurer | Karl Krushelnick | M. Aléonard

[1] U. Keller,et al. Real-time characterization and optimal phase control of tunable visible pulses with a flexible compressor , 2002 .

[2] A. Dangor,et al. Observation of a hot high-current electron beam from a self-modulated laser wakefield accelerator. , 2001, Physical review letters.

[3] D. Neely,et al. Characterization of neutral density profile in a wide range of pressure of cylindrical pulsed gas jets , 2000 .

[4] Zulfikar Najmudin,et al. Plasma Wave Generation in a Self-Focused Channel of a Relativistically Intense Laser Pulse , 1998 .

[5] V. Dananić,et al. GENERAL CRITERIA FOR THE STABILITY OF UNIAXIALLY ORDERED STATES OF INCOMMENSURATE-COMMENSURATE SYSTEMS , 1997, cond-mat/9712242.

[6] P. Sprangle,et al. ELECTRON TRAPPING IN SELF-MODULATED LASER WAKEFIELDS BY RAMAN BACKSCATTER , 1997 .

[7] S. P. Le Blanc,et al. Temporal characterization of a self-modulated laser wakefield accelerator , 1996, CLEO '97., Summaries of Papers Presented at the Conference on Lasers and Electro-Optics.

[8] Moore,et al. Temporal Evolution of Self-Modulated Laser Wakefields Measured by Coherent Thomson Scattering. , 1996, Physical review letters.

[9] W. Mori,et al. The evolution of ultra‐intense, short‐pulse lasers in underdense plasmas , 1996 .

[10] Wim Leemans,et al. Plasma guiding and wakefield generation for second-generation experiments , 1996 .

[11] Eric Esarey,et al. Overview of plasma-based accelerator concepts , 1996 .

[12] R. London,et al. Ionization‐induced refraction in recombination x‐ray lasers , 1996 .

[13] A. E. Dangor,et al. Electron acceleration from the breaking of relativistic plasma waves , 1995, Nature.

[14] Hitoshi Kobayashi,et al. High-precision pepper-pot technique for a low-emittance electron beam , 1992 .

[15] Mora,et al. Self-focusing and Raman scattering of laser pulses in tenuous plasmas. , 1992, Physical review letters.

[16] Joyce,et al. Propagation and guiding of intense laser pulses in plasmas. , 1992, Physical review letters.

[17] Sander,et al. Molecular-beam epitaxial growth and surface diffusion. , 1992, Physical review letters.

[18] Gerard Mourou,et al. Compression of amplified chirped optical pulses , 1985 .

[19] Kamińska,et al. Identification of the 0.82-eV electron trap, EL2 in GaAs, as an isolated antisite arsenic defect. , 1985, Physical review letters.

[20] T. Tajima,et al. Laser Electron Accelerator , 1979 .