Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons

Krish Bhutwala; Mathieu Bailly-Grandvaux; Joohwan Kim; Maylis Dozieres; Eric Galtier; Chandra B. Curry; Maxence Gauthier; Eric Cunningham; Hae Ja Lee; Pierre Forestier-Colleoni; Adam Higginson; Nicholas Aybar; Rui Hua; Brandon C. Edghill; Joseph Strehlow; Gilliss M. Dyer; Siegfried H. Glenzer; Jongjin B. Kim; Neil Alexander; Eduardo Del Rio; Mingsheng Wei; Yuan Ping; Andrew McKelvey; Gilbert W. Collins; Farhat N. Beg; Christopher McGuffey

doi:10.1109/TPS.2020.3009639

Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons

Krish Bhutwala, Mathieu Bailly-Grandvaux, Joohwan Kim, Maylis Dozieres, Eric Galtier, Chandra B. Curry, Maxence Gauthier, Eric Cunningham, Hae Ja Lee, Pierre Forestier-Colleoni, Adam Higginson, Nicholas Aybar, Rui Hua, Brandon C. Edghill, Joseph Strehlow, Gilliss M. Dyer, Siegfried H. Glenzer, Jongjin B. Kim, Neil Alexander, Eduardo Del RioMingsheng Wei, Yuan Ping, Andrew McKelvey, Gilbert W. Collins, Farhat N. Beg, Christopher McGuffey

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

5 Scopus citations

Abstract

High-intensity short-pulse lasers have made possible the generation of energetic proton beams, unlocking numerous applications in high energy density science. One such application is uniform and isochoric heating of materials to the warm dense matter (WDM) state. We have developed a new experimental platform to simultaneously create and probe WDM at the matter in extreme conditions (MEC) end station at the Linac Coherent Light Source (LCLS). The short pulse optical laser (delivering up to 1 J in 45 fs) and the ultrabright LCLS X-ray laser with tunable frequency, respectively, deliver high power required to heat materials to WDM and precision-timed high-resolution X-rays to probe them. The laser-accelerated proton beam driven from a flat 1.5-μ m Cu foil was first measured then directed to a secondary sample of Al or polypropylene (PP), typically 300-400~μ m away. The time evolution of the sample electron temperature was measured using streaked optical pyrometry, where we observed a peak temperature of 0.9 ± 0.15 eV on the rear surface of an Al sample heated by the proton beam. Simulations using the hybrid-PIC code LSP and the rad-hydro code HELIOS show that a measured proton beam can heat Al to approximately 4 eV and PP to 1 eV if instead focused by a hemispherical Cu target. Through additional LSP simulations, we anticipate creating hotter WDM states (20 eV) by increasing the laser energy to 10 J and keeping the other laser parameters fixed.

Original language	English (US)
Article number	9158371
Pages (from-to)	2751-2758
Number of pages	8
Journal	IEEE Transactions on Plasma Science
Volume	48
Issue number	8
DOIs	https://doi.org/10.1109/TPS.2020.3009639
State	Published - Aug 2020
Externally published	Yes

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

Keywords

Free electron lasers (FELs)
proton beams
X-ray spectroscopy

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10.1109/TPS.2020.3009639

Cite this

Bhutwala, K., Bailly-Grandvaux, M., Kim, J., Dozieres, M., Galtier, E., Curry, C. B., Gauthier, M., Cunningham, E., Lee, H. J., Forestier-Colleoni, P., Higginson, A., Aybar, N., Hua, R., Edghill, B. C., Strehlow, J., Dyer, G. M., Glenzer, S. H., Kim, J. B., Alexander, N., ... McGuffey, C. (2020). Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons. IEEE Transactions on Plasma Science, 48(8), 2751-2758. Article 9158371. https://doi.org/10.1109/TPS.2020.3009639

@article{95174849ee1c41c18338af4e06371915,

title = "Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons",

abstract = "High-intensity short-pulse lasers have made possible the generation of energetic proton beams, unlocking numerous applications in high energy density science. One such application is uniform and isochoric heating of materials to the warm dense matter (WDM) state. We have developed a new experimental platform to simultaneously create and probe WDM at the matter in extreme conditions (MEC) end station at the Linac Coherent Light Source (LCLS). The short pulse optical laser (delivering up to 1 J in 45 fs) and the ultrabright LCLS X-ray laser with tunable frequency, respectively, deliver high power required to heat materials to WDM and precision-timed high-resolution X-rays to probe them. The laser-accelerated proton beam driven from a flat 1.5-μ m Cu foil was first measured then directed to a secondary sample of Al or polypropylene (PP), typically 300-400\textasciitilde{}μ m away. The time evolution of the sample electron temperature was measured using streaked optical pyrometry, where we observed a peak temperature of 0.9 ± 0.15 eV on the rear surface of an Al sample heated by the proton beam. Simulations using the hybrid-PIC code LSP and the rad-hydro code HELIOS show that a measured proton beam can heat Al to approximately 4 eV and PP to 1 eV if instead focused by a hemispherical Cu target. Through additional LSP simulations, we anticipate creating hotter WDM states (20 eV) by increasing the laser energy to 10 J and keeping the other laser parameters fixed.",

keywords = "Free electron lasers (FELs), proton beams, X-ray spectroscopy",

author = "Krish Bhutwala and Mathieu Bailly-Grandvaux and Joohwan Kim and Maylis Dozieres and Eric Galtier and Curry, \{Chandra B.\} and Maxence Gauthier and Eric Cunningham and Lee, \{Hae Ja\} and Pierre Forestier-Colleoni and Adam Higginson and Nicholas Aybar and Rui Hua and Edghill, \{Brandon C.\} and Joseph Strehlow and Dyer, \{Gilliss M.\} and Glenzer, \{Siegfried H.\} and Kim, \{Jongjin B.\} and Neil Alexander and Rio, \{Eduardo Del\} and Mingsheng Wei and Yuan Ping and Andrew McKelvey and Collins, \{Gilbert W.\} and Beg, \{Farhat N.\} and Christopher McGuffey",

note = "Publisher Copyright: {\textcopyright} 1973-2012 IEEE.",

year = "2020",

month = aug,

doi = "10.1109/TPS.2020.3009639",

language = "English (US)",

volume = "48",

pages = "2751--2758",

journal = "IEEE Transactions on Plasma Science",

issn = "0093-3813",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

number = "8",

}

Bhutwala, K, Bailly-Grandvaux, M, Kim, J, Dozieres, M, Galtier, E, Curry, CB, Gauthier, M, Cunningham, E, Lee, HJ, Forestier-Colleoni, P, Higginson, A, Aybar, N, Hua, R, Edghill, BC, Strehlow, J, Dyer, GM, Glenzer, SH, Kim, JB, Alexander, N, Rio, ED, Wei, M, Ping, Y, McKelvey, A, Collins, GW, Beg, FN & McGuffey, C 2020, 'Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons', IEEE Transactions on Plasma Science, vol. 48, no. 8, 9158371, pp. 2751-2758. https://doi.org/10.1109/TPS.2020.3009639

Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons. / Bhutwala, Krish; Bailly-Grandvaux, Mathieu; Kim, Joohwan et al.
In: IEEE Transactions on Plasma Science, Vol. 48, No. 8, 9158371, 08.2020, p. 2751-2758.

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

TY - JOUR

T1 - Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons

AU - Bhutwala, Krish

AU - Bailly-Grandvaux, Mathieu

AU - Kim, Joohwan

AU - Dozieres, Maylis

AU - Galtier, Eric

AU - Curry, Chandra B.

AU - Gauthier, Maxence

AU - Cunningham, Eric

AU - Lee, Hae Ja

AU - Forestier-Colleoni, Pierre

AU - Higginson, Adam

AU - Aybar, Nicholas

AU - Hua, Rui

AU - Edghill, Brandon C.

AU - Strehlow, Joseph

AU - Dyer, Gilliss M.

AU - Glenzer, Siegfried H.

AU - Kim, Jongjin B.

AU - Alexander, Neil

AU - Rio, Eduardo Del

AU - Wei, Mingsheng

AU - Ping, Yuan

AU - McKelvey, Andrew

AU - Collins, Gilbert W.

AU - Beg, Farhat N.

AU - McGuffey, Christopher

PY - 2020/8

Y1 - 2020/8

N2 - High-intensity short-pulse lasers have made possible the generation of energetic proton beams, unlocking numerous applications in high energy density science. One such application is uniform and isochoric heating of materials to the warm dense matter (WDM) state. We have developed a new experimental platform to simultaneously create and probe WDM at the matter in extreme conditions (MEC) end station at the Linac Coherent Light Source (LCLS). The short pulse optical laser (delivering up to 1 J in 45 fs) and the ultrabright LCLS X-ray laser with tunable frequency, respectively, deliver high power required to heat materials to WDM and precision-timed high-resolution X-rays to probe them. The laser-accelerated proton beam driven from a flat 1.5-μ m Cu foil was first measured then directed to a secondary sample of Al or polypropylene (PP), typically 300-400~μ m away. The time evolution of the sample electron temperature was measured using streaked optical pyrometry, where we observed a peak temperature of 0.9 ± 0.15 eV on the rear surface of an Al sample heated by the proton beam. Simulations using the hybrid-PIC code LSP and the rad-hydro code HELIOS show that a measured proton beam can heat Al to approximately 4 eV and PP to 1 eV if instead focused by a hemispherical Cu target. Through additional LSP simulations, we anticipate creating hotter WDM states (20 eV) by increasing the laser energy to 10 J and keeping the other laser parameters fixed.

AB - High-intensity short-pulse lasers have made possible the generation of energetic proton beams, unlocking numerous applications in high energy density science. One such application is uniform and isochoric heating of materials to the warm dense matter (WDM) state. We have developed a new experimental platform to simultaneously create and probe WDM at the matter in extreme conditions (MEC) end station at the Linac Coherent Light Source (LCLS). The short pulse optical laser (delivering up to 1 J in 45 fs) and the ultrabright LCLS X-ray laser with tunable frequency, respectively, deliver high power required to heat materials to WDM and precision-timed high-resolution X-rays to probe them. The laser-accelerated proton beam driven from a flat 1.5-μ m Cu foil was first measured then directed to a secondary sample of Al or polypropylene (PP), typically 300-400~μ m away. The time evolution of the sample electron temperature was measured using streaked optical pyrometry, where we observed a peak temperature of 0.9 ± 0.15 eV on the rear surface of an Al sample heated by the proton beam. Simulations using the hybrid-PIC code LSP and the rad-hydro code HELIOS show that a measured proton beam can heat Al to approximately 4 eV and PP to 1 eV if instead focused by a hemispherical Cu target. Through additional LSP simulations, we anticipate creating hotter WDM states (20 eV) by increasing the laser energy to 10 J and keeping the other laser parameters fixed.

KW - Free electron lasers (FELs)

KW - proton beams

KW - X-ray spectroscopy

UR - https://www.scopus.com/pages/publications/85090029410

UR - https://www.scopus.com/inward/citedby.url?scp=85090029410&partnerID=8YFLogxK

U2 - 10.1109/TPS.2020.3009639

DO - 10.1109/TPS.2020.3009639

M3 - Article

AN - SCOPUS:85090029410

SN - 0093-3813

VL - 48

SP - 2751

EP - 2758

JO - IEEE Transactions on Plasma Science

JF - IEEE Transactions on Plasma Science

IS - 8

M1 - 9158371

ER -

Development of a Platform at the Matter in Extreme Conditions End Station for Characterization of Matter Heated by Intense Laser-Accelerated Protons

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All Science Journal Classification (ASJC) codes

Keywords

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