Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions

N. F. Beier; H. Allison; P. Efthimion; K. A. Flippo; L. Gao; S. B. Hansen; K. Hill; R. Hollinger; M. Logantha; Y. Musthafa; R. Nedbailo; V. Senthilkumaran; R. Shepherd; V. N. Shlyaptsev; H. Song; S. Wang; F. Dollar; J. J. Rocca; A. E. Hussein

doi:10.1103/PhysRevLett.129.135001

Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions

N. F. Beier
, H. Allison
, P. Efthimion
, K. A. Flippo
, L. Gao
, S. B. Hansen
, K. Hill
, R. Hollinger
, M. Logantha
, Y. Musthafa
, R. Nedbailo
, V. Senthilkumaran
, R. Shepherd
, V. N. Shlyaptsev
, H. Song
, S. Wang
, F. Dollar
, J. J. Rocca
, A. E. Hussein

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

17 Scopus citations

Abstract

Short-pulse, laser-solid interactions provide a unique platform for studying complex high-energy-density matter. We present the first demonstration of solid-density, micron-scale keV plasmas uniformly heated by a high-contrast, 400 nm wavelength laser at intensities up to 2×1021 W/cm2. High-resolution spectral analysis of x-ray emission reveals uniform heating up to 3.0 keV over 1 μm depths. Particle-in-cell simulations indicate the production of a uniformly heated keV plasma to depths of 2 μm. The significant bulk heating and presence of highly ionized ions deep within the target are attributed to the few MeV hot electrons that become trapped and undergo refluxing within the target sheath fields. These conditions enabled the differentiation of atomic physics models of ionization potential depression in high-energy-density environments.

Original language	English (US)
Article number	135001
Journal	Physical review letters
Volume	129
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevLett.129.135001
State	Published - Sep 23 2022

All Science Journal Classification (ASJC) codes

General Physics and Astronomy

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10.1103/PhysRevLett.129.135001

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Beier, N. F., Allison, H., Efthimion, P., Flippo, K. A., Gao, L., Hansen, S. B., Hill, K., Hollinger, R., Logantha, M., Musthafa, Y., Nedbailo, R., Senthilkumaran, V., Shepherd, R., Shlyaptsev, V. N., Song, H., Wang, S., Dollar, F., Rocca, J. J., & Hussein, A. E. (2022). Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions. Physical review letters, 129(13), Article 135001. https://doi.org/10.1103/PhysRevLett.129.135001

@article{735e3fae79a64a7d8f648e1b0da039cf,

title = "Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions",

abstract = "Short-pulse, laser-solid interactions provide a unique platform for studying complex high-energy-density matter. We present the first demonstration of solid-density, micron-scale keV plasmas uniformly heated by a high-contrast, 400 nm wavelength laser at intensities up to 2×1021 W/cm2. High-resolution spectral analysis of x-ray emission reveals uniform heating up to 3.0 keV over 1 μm depths. Particle-in-cell simulations indicate the production of a uniformly heated keV plasma to depths of 2 μm. The significant bulk heating and presence of highly ionized ions deep within the target are attributed to the few MeV hot electrons that become trapped and undergo refluxing within the target sheath fields. These conditions enabled the differentiation of atomic physics models of ionization potential depression in high-energy-density environments.",

author = "Beier, \{N. F.\} and H. Allison and P. Efthimion and Flippo, \{K. A.\} and L. Gao and Hansen, \{S. B.\} and K. Hill and R. Hollinger and M. Logantha and Y. Musthafa and R. Nedbailo and V. Senthilkumaran and R. Shepherd and Shlyaptsev, \{V. N.\} and H. Song and S. Wang and F. Dollar and Rocca, \{J. J.\} and Hussein, \{A. E.\}",

note = "Publisher Copyright: {\textcopyright} 2022 American Physical Society.",

year = "2022",

month = sep,

day = "23",

doi = "10.1103/PhysRevLett.129.135001",

language = "English (US)",

volume = "129",

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Beier, NF, Allison, H, Efthimion, P, Flippo, KA, Gao, L, Hansen, SB, Hill, K, Hollinger, R, Logantha, M, Musthafa, Y, Nedbailo, R, Senthilkumaran, V, Shepherd, R, Shlyaptsev, VN, Song, H, Wang, S, Dollar, F, Rocca, JJ & Hussein, AE 2022, 'Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions', Physical review letters, vol. 129, no. 13, 135001. https://doi.org/10.1103/PhysRevLett.129.135001

TY - JOUR

T1 - Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions

AU - Beier, N. F.

AU - Allison, H.

AU - Efthimion, P.

AU - Flippo, K. A.

AU - Gao, L.

AU - Hansen, S. B.

AU - Hill, K.

AU - Hollinger, R.

AU - Logantha, M.

AU - Musthafa, Y.

AU - Nedbailo, R.

AU - Senthilkumaran, V.

AU - Shepherd, R.

AU - Shlyaptsev, V. N.

AU - Song, H.

AU - Wang, S.

AU - Dollar, F.

AU - Rocca, J. J.

AU - Hussein, A. E.

PY - 2022/9/23

Y1 - 2022/9/23

N2 - Short-pulse, laser-solid interactions provide a unique platform for studying complex high-energy-density matter. We present the first demonstration of solid-density, micron-scale keV plasmas uniformly heated by a high-contrast, 400 nm wavelength laser at intensities up to 2×1021 W/cm2. High-resolution spectral analysis of x-ray emission reveals uniform heating up to 3.0 keV over 1 μm depths. Particle-in-cell simulations indicate the production of a uniformly heated keV plasma to depths of 2 μm. The significant bulk heating and presence of highly ionized ions deep within the target are attributed to the few MeV hot electrons that become trapped and undergo refluxing within the target sheath fields. These conditions enabled the differentiation of atomic physics models of ionization potential depression in high-energy-density environments.

AB - Short-pulse, laser-solid interactions provide a unique platform for studying complex high-energy-density matter. We present the first demonstration of solid-density, micron-scale keV plasmas uniformly heated by a high-contrast, 400 nm wavelength laser at intensities up to 2×1021 W/cm2. High-resolution spectral analysis of x-ray emission reveals uniform heating up to 3.0 keV over 1 μm depths. Particle-in-cell simulations indicate the production of a uniformly heated keV plasma to depths of 2 μm. The significant bulk heating and presence of highly ionized ions deep within the target are attributed to the few MeV hot electrons that become trapped and undergo refluxing within the target sheath fields. These conditions enabled the differentiation of atomic physics models of ionization potential depression in high-energy-density environments.

UR - https://www.scopus.com/pages/publications/85138764548

UR - https://www.scopus.com/pages/publications/85138764548#tab=citedBy

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DO - 10.1103/PhysRevLett.129.135001

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AN - SCOPUS:85138764548

SN - 0031-9007

VL - 129

JO - Physical review letters

JF - Physical review letters

IS - 13

M1 - 135001

ER -

Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions

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