High-pressure chemistry of hydrocarbons relevant to planetary interiors and inertial confinement fusion

Kraus, D.; Hartley, N. J.; Frydrych, S.; Schuster, A. K.; Rohatsch, K.; Rödel, Melanie; Cowan, T. E.; Brown, Shaughnessy; Cunningham, Eric; Driel, Tim van; Fletcher, L. B.; Galtier, Eric; Gamboa, E. J.; García, Alejandro Laso; Gericke, D. O.; Granados, Eduardo; Heimann, Philip; Lee, H. J.; MacDonald, M. J.; Mackinnon, A. J.; McBride, E. E.; Nam, Inhyuk; Neumayer, P.; Pak, A.; Pełka, A.; Prencipe, Irene; Ravasio, A.; Redmer, R.; Saunders, A. M.; Schölmerich, M.; Schörner, Maximilian; Sun, Peihao; Turner, Sean; Zettl, Alex; Falcone, R. W.; Glenzer, S. H.; Döppner, T.; Vorberger, Jan

doi:10.1063/1.5017908

Cited by 30 publications

(48 citation statements)

References 66 publications

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“…For the samples at ambient conditions, the diffraction signatures of both the amorphous polystyrene (the blue line-out subtracting the sharp Al Bragg peaks) as well as the thin aluminum coatings (Bragg peaks in the blue line-out) can be observed. In the driven case, the formation of compressed diamond crystallites is clearly visible, as demonstrated by the appearance of the corresponding (111) powder diffraction ring above a broader diffraction signature of a remaining warm dense CH liquid [7]. Complying with the assumption that diamond crystallites are formed in quasi-steady-state conditions after the second shock wave has passed, we do not find evidence for a preferred orientation of the crystallites.…”

Section: Methodsmentioning

confidence: 46%

“…The first compression wave (e.g., ∼60 GPa, ∼4000 K, for the intermediate drive) takes ∼7.5 ns to reach the sample rear side. The second compression wave that creates the high-pressure, high-temperature conditions required for diamond formation is launched 6 ns after the initial shock and traverses the precompressed sample volume within ∼1 ns [6,7]. Therefore, there were on average t D = 500 ps to form diamonds at the moment when the two compression waves overlap at the sample rear side.…”

Section: Resultsmentioning

confidence: 99%

“…Structural changes could be observed by in situ x-ray diffraction (XRD) with the LCLS pulses of 8. discussion of the pressure and temperature conditions reached in the experiment, can be found in Refs. [6,7].…”

Section: Methodsmentioning

confidence: 99%

“…This material mix likely undergoes chemical reactions and structural transitions due to the high-pressure, high-temperature conditions deep inside the planets' interiors [3][4][5]. A prominent example of such a reaction is the possible carbon-hydrogen dissociation and the subsequent phase separation that results in the formation of diamonds [6][7][8]. The diamonds are denser than the surrounding fluid and therefore precipitate towards the planetary centers [3].…”

Section: Introductionmentioning

confidence: 99%

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Measurement of diamond nucleation rates from hydrocarbons at conditions comparable to the interiors of icy giant planets

et al. 2020

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We present measurements of the nucleation rate into a diamond lattice in dynamically compressed polystyrene obtained in a pump-probe experiment using a high-energy laser system and in situ femtosecond x-ray diffraction. Different temperature-pressure conditions that occur in planetary interiors were probed. For a single shock reaching 70 GPa and 3000 K no diamond formation was observed, while with a double shock driving polystyrene to pressures around 150 GPa and temperatures around 5000 K nucleation rates between 10 29 and 10 34 m −3 s −1 were recorded. These nucleation rates do not agree with predictions of the state-of-the-art theoretical models for carbon-hydrogen mixtures by many orders of magnitude. Our data suggest that there is significant diamond formation to be expected inside icy giant planets like Neptune and Uranus.

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Section: Methodsmentioning

confidence: 46%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Measurement of diamond nucleation rates from hydrocarbons at conditions comparable to the interiors of icy giant planets

et al. 2020

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“…Dynamic compression experiments on hydrocarbons are used to probe their properties at combined high-pressure and -temperature conditions [33][34][35][36][37][38][39][40], both to investigate their potential decomposition, but also to better understand a critical ablator material used in inertial confinement fusion experiments. The thermal equation of state of hydrocarbons has therefore been a subject of several ab initio molecular dynamics studies [41][42][43][44][45][46].…”

Section: Introductionmentioning

confidence: 99%

High Pressure Hydrocarbons Revisited: From van der Waals Compounds to Diamond

Conway

Hermann

2019

Geosciences

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Methane and other hydrocarbons are major components of the mantle regions of icy planets. Several recent computational studies have investigated the high-pressure behaviour of specific hydrocarbons. To develop a global picture of hydrocarbon stability, to identify relevant decomposition reactions, and probe eventual formation of diamond, a complete study of all hydrocarbons is needed. Using density functional theory calculations we survey here all known C-H crystal structures augmented by targeted crystal structure searches to build hydrocarbon phase diagrams in the ground state and at elevated temperatures. We find that an updated pressure-temperature phase diagram for methane is dominated at intermediate pressures by CH 4 :H 2 van der Waals inclusion compounds. We discuss the P-T phase diagram for CH and CH 2 (i.e., polystyrene and polyethylene) to illustrate that diamond formation conditions are strongly composition dependent. Finally, crystal structure searches uncover a new CH 4 (H 2 ) 2 van der Waals compound, the most hydrogen-rich hydrocarbon, stable between 170 and 220 GPa.

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Para‐xylene under extreme conditions: A Raman spectroscopic study

Chaurasia

Rao

Mohan

2021

J Raman Spectroscopy

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Para-xylene is one of the highly used aromatic compounds in petroleum, chemical, agriculture, aviation, and polymer industries, and hence, it is necessary to study p-Xylene behavior under extreme conditions (high pressure and high temperature). Here, we report a detailed study on p-Xylene under nanosecond laser-driven dynamic compression (up to 4.5 GPa) and shock temperatures (up to 1,300 K). The experimental observations are compared with previous reported study using hydrostatic compression. A time-resolved Raman spectroscopy is also done for the estimation of shock velocity in the p-Xylene sample using the intensity ratio of the Raman modes from the shocked region to that of the whole sample region. The shock velocities for the laser energy on sample at 700 mJ (corresponding pressure 2.5 GPa) deduced by the Raman active modes at 810, 827, and 1204 cm −1 are 3.60 ± 0.46, 3.67 ± 0.17, and 3.78 ±0.09 km/s, respectively. One-dimensional (1-D) radiation hydrodynamic simulation is also performed for the validation of experimental results. The shock velocity from the simulation at the same laser energy is 3.51 km/s and is in good agreement with the experimental data. The Gruneisen parameters calculated for various Raman modes such as ν 10 (644 cm −1 ), ν 13 (810 cm −1 ), ν 14 (827 cm −1 ), ν 18 (1,204 cm −1 ), ν 27 (2,863 cm −1 ), ν 30 (3,011 cm −1 ), and ν 31 (3,053 cm −1 ) are γ i = 0.

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High-pressure chemistry of hydrocarbons relevant to planetary interiors and inertial confinement fusion

Cited by 30 publications

References 66 publications

Measurement of diamond nucleation rates from hydrocarbons at conditions comparable to the interiors of icy giant planets

Measurement of diamond nucleation rates from hydrocarbons at conditions comparable to the interiors of icy giant planets

High Pressure Hydrocarbons Revisited: From van der Waals Compounds to Diamond

Para‐xylene under extreme conditions: A Raman spectroscopic study

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