A cascaded laser acceleration scheme for the generation of spectrally controlled proton beams

S. M. Pfotenhauer; O. Jäckel; J. Polz; S. Steinke; H. P. Schlenvoigt; J. Heymann; A. P.L. Robinson; M. C. Kaluza

doi:10.1088/1367-2630/12/10/103009

A cascaded laser acceleration scheme for the generation of spectrally controlled proton beams

S. M. Pfotenhauer, O. Jäckel, J. Polz, S. Steinke, H. P. Schlenvoigt, J. Heymann, A. P.L. Robinson, M. C. Kaluza

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

37 Scopus citations

Abstract

We present a novel, cascaded acceleration scheme for the generation of spectrally controlled ion beams using a laser-based accelerator in a 'double-stage' setup. An MeV proton beam produced during a relativistic laser-plasma interaction on a thin foil target is spectrally shaped by a secondary laser-plasma interaction on a separate foil, reliably creating well-separated quasi-monoenergetic features in the energy spectrum. The observed modulations are fully explained by a one-dimensional (1D) model supported by numerical simulations. These findings demonstrate that laser acceleration can, in principle, be applied in an additive manner.

Original language	English
Article number	103009
Journal	New Journal of Physics
Volume	12
DOIs	https://doi.org/10.1088/1367-2630/12/10/103009
State	Published - 5 Oct 2010
Externally published	Yes

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abstract = "We present a novel, cascaded acceleration scheme for the generation of spectrally controlled ion beams using a laser-based accelerator in a 'double-stage' setup. An MeV proton beam produced during a relativistic laser-plasma interaction on a thin foil target is spectrally shaped by a secondary laser-plasma interaction on a separate foil, reliably creating well-separated quasi-monoenergetic features in the energy spectrum. The observed modulations are fully explained by a one-dimensional (1D) model supported by numerical simulations. These findings demonstrate that laser acceleration can, in principle, be applied in an additive manner.",

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AU - Pfotenhauer, S. M.

AU - Jäckel, O.

AU - Polz, J.

AU - Steinke, S.

AU - Schlenvoigt, H. P.

AU - Heymann, J.

AU - Robinson, A. P.L.

AU - Kaluza, M. C.

PY - 2010/10/5

Y1 - 2010/10/5

N2 - We present a novel, cascaded acceleration scheme for the generation of spectrally controlled ion beams using a laser-based accelerator in a 'double-stage' setup. An MeV proton beam produced during a relativistic laser-plasma interaction on a thin foil target is spectrally shaped by a secondary laser-plasma interaction on a separate foil, reliably creating well-separated quasi-monoenergetic features in the energy spectrum. The observed modulations are fully explained by a one-dimensional (1D) model supported by numerical simulations. These findings demonstrate that laser acceleration can, in principle, be applied in an additive manner.

AB - We present a novel, cascaded acceleration scheme for the generation of spectrally controlled ion beams using a laser-based accelerator in a 'double-stage' setup. An MeV proton beam produced during a relativistic laser-plasma interaction on a thin foil target is spectrally shaped by a secondary laser-plasma interaction on a separate foil, reliably creating well-separated quasi-monoenergetic features in the energy spectrum. The observed modulations are fully explained by a one-dimensional (1D) model supported by numerical simulations. These findings demonstrate that laser acceleration can, in principle, be applied in an additive manner.

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A cascaded laser acceleration scheme for the generation of spectrally controlled proton beams

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