Isochoric Heating of Solid-Density Matter with an Ultrafast Proton Beam

Patel, P. K.; Mackinnon, A. J.; Key, M. H.; Cowan, T. E.; Foord, Mark; Allen, M.; Price, D.; Rühl, H.; Springer, P. T.; Stephens, R. B.

doi:10.1103/physrevlett.91.125004

Cited by 567 publications

(312 citation statements)

References 20 publications

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“…The temporal characteristics of the proton emission have been discussed theoretically and are supported by experimentally gained arguments in several publications [1,3,93,101,102]. The acceleration of the protons takes place on a picosecond timescale.…”

Section: Chapter 7 Virtual Source Dynamicsmentioning

confidence: 63%

“…The proton beam usually has a broad and continuous energy distribution -but the energetic protons are all accelerated within 1-2 ps [1,3,93,101,102]. Starting at nearly the same time from the target, they reach the interaction target at different times.…”

Section: Principle Of Proton Imagingmentioning

confidence: 99%

“…That means that the instantaneous frequency is changing in time. If the frequency increases/decreases the pulse is called up-/down-chirped 1 . A pulse with dω(t)/dt = d 2 ϕ(t)/dt 2 = a 2 = const is called linearly chirped, the frequency is changing linearly in time.…”

Section: Mathematical Descriptionmentioning

confidence: 99%

“…Different applications established recently benefit from these beam attributes. High-energy-density matter can be created, which is of interest for astrophysics [1,2]. Furthermore, these beams are predestined for temporally and 1 spatially resolved pump-probe experiments.…”

Section: Introductionmentioning

confidence: 99%

“…By using curved targets the emission angle of the ion beam can be influenced. Concave targets can focus or collimate the whole ion beam [1,[10][11][12]. To achieve tailored spectra, especially monoenergetic ion beams, different approaches exist.…”

Section: Introductionmentioning

confidence: 99%

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Investigations of Field Dynamics in Laser Plasmas with Proton Imaging

Sokollik

2011

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Section: Chapter 7 Virtual Source Dynamicsmentioning

confidence: 63%

Section: Principle Of Proton Imagingmentioning

confidence: 99%

Section: Mathematical Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Investigations of Field Dynamics in Laser Plasmas with Proton Imaging

Sokollik

2011

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Survey of Theoretical Work for the Proposed HEDgeHOB Experimental Schemes: HIHEX and LAPLAS

Tahir

Piriz

Shutov

et al. 2007

Contrib. Plasma Phys.

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This paper presents a review of the theoretical work that has resulted in a scientific proposal on studies of HighEnergy-Density (HED) states in matter using intense beams of energetic heavy ions that will be available at the future Facility for Antiprotons and Ion Research (FAIR) at Darmstadt [W.F. Henning, Nucl. Inst. Meth B 24 (2003) [725][726][727][728][729]. The proposal is named HEDgeHOB that stands for High Energy Density Matter Generated by Heavy Ion Beams. Two experimental schemes have been worked out for the HEDgeHOB experimental proposal, namely, HIHEX and LAPLAS. The first scheme allows for studies of HED states by isochoric and uniform heating of matter by an intense heavy ion beam that is followed by isentropic expansion of the heated material. Numerical simulations have shown that using the beam parameters that will be available at the FAIR, one can access all the interesting physical states of HED matter including an expanded hot liquid state, twophase liquid-gas region, critical point parameters and strongly coupled plasmas for all the materials of interest. The second scheme involves a low-entropy compression of a test material like hydrogen that is enclosed in a cylindrical shell of a high-Z material like gold or lead. The target can be driven by a hollow or a circular beam. This compression scheme relies on multiple shock reflection between the hydrogen-gold (lead) boundary and the cylinder axis. The hydrodynamic stability of the LAPLAS target has also been analyzed that shows that the implosion is completely stable to Rayleigh-Taylor and Richtmyer-Meshkov instabilities. LAPLAS implosion using a hollow beam is suitable for studying the problem of hydrogen metallization whereas the one employing a circular focal spot leads to physical conditions that are expected to exist in the interiors of the giant planets.

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Excited States of Warm Dense Matter

Norman

Skobelev

Stegaĭlov

2011

Contrib. Plasma Phys.

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The excited states of the warm dense matter (WDM) are considered. The main attention is paid to the so called structured warm dense matter (SWDM). The SWDM has partly (or fully) ionized plasma properties as well as crystal ones. The methods for WDM creation is described shortly. We give situations where SWDM demonstrates crystal or plasma features. The finite temperature density functional theory approach is deployed for description of the fcc LiF crystal in a two-temperature warm dense matter state with hot electrons and cold lattice that is formed after ultrafast energy deposition. The lattice stability and the interatomic bonding at elevated electronic temperatures are studied. The methods of molecular dynamics and collisional-radiative kinetics are used to investigate the plasma properties of WDM.

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Isochoric Heating of Solid-Density Matter with an Ultrafast Proton Beam

Cited by 567 publications

References 20 publications

Investigations of Field Dynamics in Laser Plasmas with Proton Imaging

Investigations of Field Dynamics in Laser Plasmas with Proton Imaging

Survey of Theoretical Work for the Proposed HEDgeHOB Experimental Schemes: HIHEX and LAPLAS

Excited States of Warm Dense Matter

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