Non-Maxwellian electron distributions resulting from direct laser acceleration in near-critical plasmas

T. Toncian; C. Wang; E. McCary; A. Meadows; A. V. Arefiev; J. Blakeney; K. Serratto; D. Kuk; C. Chester; R. Roycroft; L. Gao; H. Fu; X. Q. Yan; J. Schreiber; I. Pomerantz; A. Bernstein; H. Quevedo; G. Dyer; T. Ditmire; B. M. Hegelich

doi:https://doi.org/10.1016/j.mre.2015.11.001

Non-Maxwellian electron distributions resulting from direct laser acceleration in near-critical plasmas

T. Toncian, C. Wang, E. McCary, A. Meadows, A. V. Arefiev, J. Blakeney, K. Serratto, D. Kuk, C. Chester, R. Roycroft, L. Gao, H. Fu, X. Q. Yan, J. Schreiber, I. Pomerantz, A. Bernstein, H. Quevedo, G. Dyer, T. Ditmire, B. M. Hegelich

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

Abstract

The irradiation of few-nm-thick targets by a finite-contrast high-intensity short-pulse laser results in a strong pre-expansion of these targets at the arrival time of the main pulse. The targets decompress to near and lower than critical densities with plasmas extending over few micrometers, i.e. multiple wavelengths. The interaction of the main pulse with such a highly localized but inhomogeneous target leads to the generation of a short channel and further self-focusing of the laser beam. Experiments at the Glass Hybrid OPCPA Scaled Test-bed (GHOST) laser system at University of Texas, Austin using such targets measured non-Maxwellian, peaked electron distribution with large bunch charge and high electron density in the laser propagation direction. These results are reproduced in 2D PIC simulations using the EPOCH code, identifying direct laser acceleration (DLA) [1] as the responsible mechanism. This is the first time that DLA has been observed to produce peaked spectra as opposed to broad, Maxwellian spectra observed in earlier experiments [2]. This high-density electrons have potential applications as injector beams for a further wakefield acceleration stage as well as for pump-probe applications.

Original language	English
Pages (from-to)	82-87
Number of pages	6
Journal	Matter and Radiation at Extremes
Volume	1
Issue number	1
DOIs	https://doi.org/10.1016/j.mre.2015.11.001
State	Published - Jan 2016
Externally published	Yes

Keywords

Direct laser acceleration
Electron acceleration
Near critical plasmas
PIC simulations

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Atomic and Molecular Physics, and Optics
Electrical and Electronic Engineering
Nuclear Energy and Engineering

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https://doi.org/10.1016/j.mre.2015.11.001

Cite this

Toncian, T., Wang, C., McCary, E., Meadows, A., Arefiev, A. V., Blakeney, J., Serratto, K., Kuk, D., Chester, C., Roycroft, R., Gao, L., Fu, H., Yan, X. Q., Schreiber, J., Pomerantz, I., Bernstein, A., Quevedo, H., Dyer, G., Ditmire, T., & Hegelich, B. M. (2016). Non-Maxwellian electron distributions resulting from direct laser acceleration in near-critical plasmas. Matter and Radiation at Extremes, 1(1), 82-87. https://doi.org/10.1016/j.mre.2015.11.001

@article{4565457f8b3b4e6497eb1d5aa09e1413,

title = "Non-Maxwellian electron distributions resulting from direct laser acceleration in near-critical plasmas",

abstract = "The irradiation of few-nm-thick targets by a finite-contrast high-intensity short-pulse laser results in a strong pre-expansion of these targets at the arrival time of the main pulse. The targets decompress to near and lower than critical densities with plasmas extending over few micrometers, i.e. multiple wavelengths. The interaction of the main pulse with such a highly localized but inhomogeneous target leads to the generation of a short channel and further self-focusing of the laser beam. Experiments at the Glass Hybrid OPCPA Scaled Test-bed (GHOST) laser system at University of Texas, Austin using such targets measured non-Maxwellian, peaked electron distribution with large bunch charge and high electron density in the laser propagation direction. These results are reproduced in 2D PIC simulations using the EPOCH code, identifying direct laser acceleration (DLA) [1] as the responsible mechanism. This is the first time that DLA has been observed to produce peaked spectra as opposed to broad, Maxwellian spectra observed in earlier experiments [2]. This high-density electrons have potential applications as injector beams for a further wakefield acceleration stage as well as for pump-probe applications.",

keywords = "Direct laser acceleration, Electron acceleration, Near critical plasmas, PIC simulations",

author = "T. Toncian and C. Wang and E. McCary and A. Meadows and Arefiev, {A. V.} and J. Blakeney and K. Serratto and D. Kuk and C. Chester and R. Roycroft and L. Gao and H. Fu and Yan, {X. Q.} and J. Schreiber and I. Pomerantz and A. Bernstein and H. Quevedo and G. Dyer and T. Ditmire and Hegelich, {B. M.}",

note = "Publisher Copyright: {\textcopyright} 2016 Science and Technology Information Center, China Academy of Engineering Physics",

year = "2016",

month = jan,

doi = "https://doi.org/10.1016/j.mre.2015.11.001",

language = "الإنجليزيّة",

volume = "1",

pages = "82--87",

journal = "Matter and Radiation at Extremes",

issn = "2468-2047",

publisher = "American Institute of Physics",

number = "1",

}

Toncian, T, Wang, C, McCary, E, Meadows, A, Arefiev, AV, Blakeney, J, Serratto, K, Kuk, D, Chester, C, Roycroft, R, Gao, L, Fu, H, Yan, XQ, Schreiber, J, Pomerantz, I, Bernstein, A, Quevedo, H, Dyer, G, Ditmire, T & Hegelich, BM 2016, 'Non-Maxwellian electron distributions resulting from direct laser acceleration in near-critical plasmas', Matter and Radiation at Extremes, vol. 1, no. 1, pp. 82-87. https://doi.org/10.1016/j.mre.2015.11.001

TY - JOUR

T1 - Non-Maxwellian electron distributions resulting from direct laser acceleration in near-critical plasmas

AU - Toncian, T.

AU - Wang, C.

AU - McCary, E.

AU - Meadows, A.

AU - Arefiev, A. V.

AU - Blakeney, J.

AU - Serratto, K.

AU - Kuk, D.

AU - Chester, C.

AU - Roycroft, R.

AU - Gao, L.

AU - Fu, H.

AU - Yan, X. Q.

AU - Schreiber, J.

AU - Pomerantz, I.

AU - Bernstein, A.

AU - Quevedo, H.

AU - Dyer, G.

AU - Ditmire, T.

AU - Hegelich, B. M.

PY - 2016/1

Y1 - 2016/1

N2 - The irradiation of few-nm-thick targets by a finite-contrast high-intensity short-pulse laser results in a strong pre-expansion of these targets at the arrival time of the main pulse. The targets decompress to near and lower than critical densities with plasmas extending over few micrometers, i.e. multiple wavelengths. The interaction of the main pulse with such a highly localized but inhomogeneous target leads to the generation of a short channel and further self-focusing of the laser beam. Experiments at the Glass Hybrid OPCPA Scaled Test-bed (GHOST) laser system at University of Texas, Austin using such targets measured non-Maxwellian, peaked electron distribution with large bunch charge and high electron density in the laser propagation direction. These results are reproduced in 2D PIC simulations using the EPOCH code, identifying direct laser acceleration (DLA) [1] as the responsible mechanism. This is the first time that DLA has been observed to produce peaked spectra as opposed to broad, Maxwellian spectra observed in earlier experiments [2]. This high-density electrons have potential applications as injector beams for a further wakefield acceleration stage as well as for pump-probe applications.

AB - The irradiation of few-nm-thick targets by a finite-contrast high-intensity short-pulse laser results in a strong pre-expansion of these targets at the arrival time of the main pulse. The targets decompress to near and lower than critical densities with plasmas extending over few micrometers, i.e. multiple wavelengths. The interaction of the main pulse with such a highly localized but inhomogeneous target leads to the generation of a short channel and further self-focusing of the laser beam. Experiments at the Glass Hybrid OPCPA Scaled Test-bed (GHOST) laser system at University of Texas, Austin using such targets measured non-Maxwellian, peaked electron distribution with large bunch charge and high electron density in the laser propagation direction. These results are reproduced in 2D PIC simulations using the EPOCH code, identifying direct laser acceleration (DLA) [1] as the responsible mechanism. This is the first time that DLA has been observed to produce peaked spectra as opposed to broad, Maxwellian spectra observed in earlier experiments [2]. This high-density electrons have potential applications as injector beams for a further wakefield acceleration stage as well as for pump-probe applications.

KW - Direct laser acceleration

KW - Electron acceleration

KW - Near critical plasmas

KW - PIC simulations

UR - http://www.scopus.com/inward/record.url?scp=84965058984&partnerID=8YFLogxK

U2 - https://doi.org/10.1016/j.mre.2015.11.001

DO - https://doi.org/10.1016/j.mre.2015.11.001

M3 - مقالة

SN - 2468-2047

VL - 1

SP - 82

EP - 87

JO - Matter and Radiation at Extremes

JF - Matter and Radiation at Extremes

IS - 1

ER -

Non-Maxwellian electron distributions resulting from direct laser acceleration in near-critical plasmas

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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