Laser triggered micro-lens for focusing and energy selection of MeV protons

O. Willi; T. Toncian; M. Borghesi; J. Fuchs; E. D'Humières; P. Antici; P. Audebert; E. Brambrink; C. Cecchetti; A. Pipahl; L. Romagnani

doi:10.1017/S0263034607070115

Laser triggered micro-lens for focusing and energy selection of MeV protons

O. Willi, T. Toncian, M. Borghesi, J. Fuchs, E. D'Humières, P. Antici, P. Audebert, E. Brambrink, C. Cecchetti, A. Pipahl, L. Romagnani

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

Abstract

We present a novel technique for focusing and energy selection of high-current, MeV proton/ion beams. This method employs a hollow micro-cylinder that is irradiated at the outer wall by a high intensity, ultra-short laser pulse. The relativistic electrons produced are injected through the cylinder's wall, spread evenly on the inner wall surface of the cylinder, and initiate a hot plasma expansion. A transient radial electric field (10⁷-10 ¹⁰ V/m) is associated with the expansion. The transient electrostatic field induces the focusing and the selection of a narrow band component out of the broadband poly-energetic energy spectrum of the protons generated from a separate laser irradiated thin foil target that are directed axially through the cylinder. The energy selection is tunable by changing the timing of the two laser pulses. Computer simulations carried out for similar parameters as used in the experiments explain the working of the micro-lens.

Original language	English
Pages (from-to)	71-77
Number of pages	7
Journal	Laser and Particle Beams
Volume	25
Issue number	1
DOIs	https://doi.org/10.1017/S0263034607070115
Publication status	Published - 1 Jan 2007

Keywords

Laser triggered ion micro-lens
Proton focusing
Quasi mono-energetic proton beam

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10.1017/S0263034607070115

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title = "Laser triggered micro-lens for focusing and energy selection of MeV protons",

abstract = "We present a novel technique for focusing and energy selection of high-current, MeV proton/ion beams. This method employs a hollow micro-cylinder that is irradiated at the outer wall by a high intensity, ultra-short laser pulse. The relativistic electrons produced are injected through the cylinder's wall, spread evenly on the inner wall surface of the cylinder, and initiate a hot plasma expansion. A transient radial electric field (107-10 10 V/m) is associated with the expansion. The transient electrostatic field induces the focusing and the selection of a narrow band component out of the broadband poly-energetic energy spectrum of the protons generated from a separate laser irradiated thin foil target that are directed axially through the cylinder. The energy selection is tunable by changing the timing of the two laser pulses. Computer simulations carried out for similar parameters as used in the experiments explain the working of the micro-lens.",

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author = "O. Willi and T. Toncian and M. Borghesi and J. Fuchs and E. D'Humi{\`e}res and P. Antici and P. Audebert and E. Brambrink and C. Cecchetti and A. Pipahl and L. Romagnani",

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TY - JOUR

T1 - Laser triggered micro-lens for focusing and energy selection of MeV protons

AU - Willi, O.

AU - Toncian, T.

AU - Borghesi, M.

AU - Fuchs, J.

AU - D'Humières, E.

AU - Antici, P.

AU - Audebert, P.

AU - Brambrink, E.

AU - Cecchetti, C.

AU - Pipahl, A.

AU - Romagnani, L.

PY - 2007/1/1

Y1 - 2007/1/1

N2 - We present a novel technique for focusing and energy selection of high-current, MeV proton/ion beams. This method employs a hollow micro-cylinder that is irradiated at the outer wall by a high intensity, ultra-short laser pulse. The relativistic electrons produced are injected through the cylinder's wall, spread evenly on the inner wall surface of the cylinder, and initiate a hot plasma expansion. A transient radial electric field (107-10 10 V/m) is associated with the expansion. The transient electrostatic field induces the focusing and the selection of a narrow band component out of the broadband poly-energetic energy spectrum of the protons generated from a separate laser irradiated thin foil target that are directed axially through the cylinder. The energy selection is tunable by changing the timing of the two laser pulses. Computer simulations carried out for similar parameters as used in the experiments explain the working of the micro-lens.

AB - We present a novel technique for focusing and energy selection of high-current, MeV proton/ion beams. This method employs a hollow micro-cylinder that is irradiated at the outer wall by a high intensity, ultra-short laser pulse. The relativistic electrons produced are injected through the cylinder's wall, spread evenly on the inner wall surface of the cylinder, and initiate a hot plasma expansion. A transient radial electric field (107-10 10 V/m) is associated with the expansion. The transient electrostatic field induces the focusing and the selection of a narrow band component out of the broadband poly-energetic energy spectrum of the protons generated from a separate laser irradiated thin foil target that are directed axially through the cylinder. The energy selection is tunable by changing the timing of the two laser pulses. Computer simulations carried out for similar parameters as used in the experiments explain the working of the micro-lens.

KW - Laser triggered ion micro-lens

KW - Proton focusing

KW - Quasi mono-energetic proton beam

U2 - 10.1017/S0263034607070115

DO - 10.1017/S0263034607070115

M3 - Article

AN - SCOPUS:33947378785

SN - 0263-0346

VL - 25

SP - 71

EP - 77

JO - Laser and Particle Beams

JF - Laser and Particle Beams

IS - 1

ER -

Laser triggered micro-lens for focusing and energy selection of MeV protons

Abstract

Keywords

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