Proton acceleration by single-cycle laser pulses offers a novel monoenergetic and stable operating regime

M. L. Zhou; X. Q. Yan; G. Mourou; J. A. Wheeler; J. H. Bin; J. Schreiber; T. Tajima

doi:10.1063/1.4947544

Proton acceleration by single-cycle laser pulses offers a novel monoenergetic and stable operating regime

M. L. Zhou
, X. Q. Yan
, G. Mourou
, J. A. Wheeler
, J. H. Bin
, J. Schreiber
, T. Tajima

Tsinghua University
Universität München
Shanxi University
Ecole Polytechnique, IZEST
Long Beach VA and University of California

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

Abstract

Prompted by the possibility to produce high energy, single-cycle laser pulses with tens of Petawatt (PW) power, we have investigated laser-matter interactions in the few optical cycle and ultra relativistic intensity regimes. A particularly interesting instability-free regime for ion production was revealed leading to the efficient coherent generation of short (femtosecond; 10 - 15 s) monoenergetic ion bunches with a peak energy greater than GeV. Of paramount importance, the interaction is absent of the Rayleigh Taylor Instabilities and hole boring that plague techniques such as target normal sheath acceleration and radiation pressure acceleration.

Original language	English
Article number	043112
Journal	Physics of Plasmas
Volume	23
Issue number	4
DOIs	https://doi.org/10.1063/1.4947544
Publication status	Published - 1 Apr 2016
Externally published	Yes

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10.1063/1.4947544

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title = "Proton acceleration by single-cycle laser pulses offers a novel monoenergetic and stable operating regime",

abstract = "Prompted by the possibility to produce high energy, single-cycle laser pulses with tens of Petawatt (PW) power, we have investigated laser-matter interactions in the few optical cycle and ultra relativistic intensity regimes. A particularly interesting instability-free regime for ion production was revealed leading to the efficient coherent generation of short (femtosecond; 10 - 15 s) monoenergetic ion bunches with a peak energy greater than GeV. Of paramount importance, the interaction is absent of the Rayleigh Taylor Instabilities and hole boring that plague techniques such as target normal sheath acceleration and radiation pressure acceleration.",

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T1 - Proton acceleration by single-cycle laser pulses offers a novel monoenergetic and stable operating regime

AU - Zhou, M. L.

AU - Yan, X. Q.

AU - Mourou, G.

AU - Wheeler, J. A.

AU - Bin, J. H.

AU - Schreiber, J.

AU - Tajima, T.

PY - 2016/4/1

Y1 - 2016/4/1

N2 - Prompted by the possibility to produce high energy, single-cycle laser pulses with tens of Petawatt (PW) power, we have investigated laser-matter interactions in the few optical cycle and ultra relativistic intensity regimes. A particularly interesting instability-free regime for ion production was revealed leading to the efficient coherent generation of short (femtosecond; 10 - 15 s) monoenergetic ion bunches with a peak energy greater than GeV. Of paramount importance, the interaction is absent of the Rayleigh Taylor Instabilities and hole boring that plague techniques such as target normal sheath acceleration and radiation pressure acceleration.

AB - Prompted by the possibility to produce high energy, single-cycle laser pulses with tens of Petawatt (PW) power, we have investigated laser-matter interactions in the few optical cycle and ultra relativistic intensity regimes. A particularly interesting instability-free regime for ion production was revealed leading to the efficient coherent generation of short (femtosecond; 10 - 15 s) monoenergetic ion bunches with a peak energy greater than GeV. Of paramount importance, the interaction is absent of the Rayleigh Taylor Instabilities and hole boring that plague techniques such as target normal sheath acceleration and radiation pressure acceleration.

U2 - 10.1063/1.4947544

DO - 10.1063/1.4947544

M3 - Article

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VL - 23

JO - Physics of Plasmas

JF - Physics of Plasmas

IS - 4

M1 - 043112

ER -

Proton acceleration by single-cycle laser pulses offers a novel monoenergetic and stable operating regime

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