Matter and Radiation at Extremes

Lan Ke

2024, 9(1) doi: 10.1063/5.0187709

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The acceleration of a high-charge electron bunch to 10 GeV in a 10-cm nanoparticle-assisted wakefield accelerator

Aniculaesei Constantin, Ha Thanh, Yoffe Samuel, Labun Lance, Milton Stephen, McCary Edward, Spinks Michael M., Quevedo Hernan J., Labun Ou Z., Sain Ritwik, Hannasch Andrea, Zgadzaj Rafal, Pagano Isabella, Franco-Altamirano Jose A., Ringuette Martin L., Gaul Erhart, Luedtke Scott V., Tiwari Ganesh, Ersfeld Bernhard, Brunetti Enrico, Ruhl Hartmut, Ditmire Todd, Bruce Sandra, Donovan Michael E., Downer Michael C., Jaroszynski Dino A., Hegelich Bjorn Manuel

2024, 9(1) doi: 10.1063/5.0161687

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An intense laser pulse focused onto a plasma can excite nonlinear plasma waves. Under appropriate conditions, electrons from the background plasma are trapped in the plasma wave and accelerated to ultra-relativistic velocities. This scheme is called a laser wakefield accelerator. In this work, we present results from a laser wakefield acceleration experiment using a petawatt-class laser to excite the wakefields as well as nanoparticles to assist the injection of electrons into the accelerating phase of the wakefields. We find that a 10-cm-long, nanoparticle-assisted laser wakefield accelerator can generate 340 pC, 10 ± 1.86 GeV electron bunches with a 3.4 GeV rms convolved energy spread and a 0.9 mrad rms divergence. It can also produce bunches with lower energies in the 4–6 GeV range.

Semi-hydro-equivalent design and performance extrapolation between 100 kJ-scale and NIF-scale indirect drive implosion

Zhang Huasen, Kang Dongguo, Wu Changshu, Hao Liang, Shen Hao, Zou Shiyang, Zhu Shaoping, Ding Yongkun

2024, 9(1) doi: 10.1063/5.0150343

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Extrapolation of implosion performance between different laser energy scales is investigated for indirect drive through a semi-hydro-equivalent design. Since radiation transport is non-hydro-equivalent, the peak radiation temperature of the hohlraum and the ablation velocity of the capsule ablator are not scale-invariant when the sizes of the hohlraum and the capsule are scale-varied. A semi-hydro-equivalent design method that keeps the implosion velocity V_i, adiabat α_F, and PL/Rhc2 (where P_L is the laser power and R_hc is the hohlraum and capsule scale length) scale-invariant, is proposed to create hydrodynamically similar implosions. The semi-hydro-equivalent design and the scaled implosion performance are investigated for the 100 kJ Laser Facility (100 kJ-scale) and the National Ignition Facility (NIF-scale) with about 2 MJ laser energy. It is found that the one-dimensional implosion performance is approximately hydro-equivalent when V_i and α_F are kept the same. Owing to the non-hydro-equivalent radiation transport, the yield-over-clean without α-particle heating (YOC_noα) is slightly lower at 100 kJ-scale than at NIF-scale for the same scaled radiation asymmetry or the same initial perturbation of the hydrodynamic instability. The overall scaled two-dimensional implosion performance is slightly lower at 100 kJ-scale. The general Lawson criterion factor scales as χnoα2D∼S1.06±0.04 (where S is the scale-variation factor) for the semi-hydro-equivalent implosion design with a moderate YOC_noα. Our study indicates that χ_noα ≈ 0.379 is the minimum requirement for the 100 kJ-scale implosion to demonstrate the ability to achieve marginal ignition at NIF-scale.

Backward scattering of laser plasma interactions from hundreds-of-joules broadband laser on thick target

Wang Peipei, An Honghai, Fang Zhiheng, Xiong Jun, Xie Zhiyong, Wang Chen, He Zhiyu, Jia Guo, Wang Ruirong, Zheng Shu, Xia Lan, Feng Wei, Shi Haitao, Wang Wei, Sun Jinren, Gao Yanqi, Fu Sizu

2024, 9(1) doi: 10.1063/5.0122406

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The use of broadband laser technology is a novel approach for inhibiting processes related to laser plasma interactions (LPIs). In this study, several preliminary experiments into broadband-laser-driven LPIs are carried out using a newly established hundreds-of-joules broadband second-harmonic-generation laser facility. Through direct comparison with LPI results for a traditional narrowband laser, the actual LPI-suppression effect of the broadband laser is shown. The broadband laser had a clear suppressive effect on both back-stimulated Raman scattering and back-stimulated Brillouin scattering at laser intensities below 1 × 10¹⁵ W cm⁻². An abnormal hot-electron phenomenon is also investigated, using targets of different thicknesses.

Resistive field generation in intense proton beam interaction with solid targets

Wang W. Q., Honrubia J. J., Yin Y., Yang X. H., Shao F. Q.

2024, 9(1) doi: 10.1063/5.0172035

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The Brown–Preston–Singleton (BPS) stopping power model is added to our previously developed hybrid code to model ion beam–plasma interaction. Hybrid simulations show that both resistive field and ion scattering effects are important for proton beam transport in a solid target, in which they compete with each other. When the target is not completely ionized, the self-generated resistive field effect dominates over the ion scattering effect. However, when the target is completely ionized, this situation is reversed. Moreover, it is found that Ohmic heating is important for higher current densities and materials with high resistivity. The energy fraction deposited as Ohmic heating can be as high as 20%–30%. Typical ion divergences with half-angles of about 5°–10° will modify the proton energy deposition substantially and should be taken into account.

Combining stochastic density functional theory with deep potential molecular dynamics to study warm dense matter

Chen Tao, Liu Qianrui, Liu Yu, Sun Liang, Chen Mohan

2024, 9(1) doi: 10.1063/5.0163303

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In traditional finite-temperature Kohn–Sham density functional theory (KSDFT), the partial occupation of a large number of high-energy KS eigenstates restricts the use of first-principles molecular dynamics methods at extremely high temperatures. However, stochastic density functional theory (SDFT) can overcome this limitation. Recently, SDFT and the related mixed stochastic–deterministic density functional theory, based on a plane-wave basis set, have been implemented in the first-principles electronic structure software ABACUS [Q. Liu and M. Chen, Phys. Rev. B 106 , 125132 (2022)]. In this study, we combine SDFT with the Born–Oppenheimer molecular dynamics method to investigate systems with temperatures ranging from a few tens of eV to 1000 eV. Importantly, we train machine-learning-based interatomic models using the SDFT data and employ these deep potential models to simulate large-scale systems with long trajectories. Subsequently, we compute and analyze the structural properties, dynamic properties, and transport coefficients of warm dense matter.

Nonstationary laser-supported ionization wave in layer of porous substance with subcritical density

Gus’kov S. Yu, Yakhin R. A.

2024, 9(1) doi: 10.1063/5.0157904

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A time-dependent analytical solution is found for the velocity of a plane ionization wave generated under nanosecond laser pulse action on the surface of a flat layer of low-Z porous substance with density less than the critical density of the produced plasma. With corrections for the two-dimensional nature of the problem when a laser beam of finite radius interacts with a flat target, this solution is in quantitative agreement with measurements of ionization wave velocity in various experiments. The solution compared with experimental data covering wide ranges of performance conditions, namely, (3–8) × 10¹⁴ W cm⁻² for laser pulse intensity, 0.3–3 ns for pulse duration, 0.35–0.53 μm for laser wavelength, 100–1000 μm for laser beam radius, 380–950 μm for layer thickness, 4.5–12 mg cm⁻³ for average density of porous substance, and 1–25 μm for average pore size. The parameters of the laser beam that ensure the generation of a plane ionization wave in a layer of subcritical porous matter are determined for the problem statements and are found to meet the requirements of practical applications.

Ion emission from warm dense matter produced by irradiation with a soft x-ray free-electron laser

Krása Josef, Burian Tomáš, Hájková Věra, Chalupský Jaromír, Jelínek Šimon, Frantálová Kateřina, Krupka Michal, Kuglerová Zuzana, Singh Sushil Kumar, Vozda Vojtěch, Vyšín Luděk, Šmíd Michal, Perez-Martin Pablo, Kühlman Marion, Pintor Juan, Cikhardt Jakub, Dreimann Matthias, Eckermann Dennis, Rosenthal Felix, Vinko Sam M., Forte Alessandro, Gawne Thomas, Campbell Thomas, Ren Shenyuan, Shi YuanFeng, Hutchinson Trevor, Humphries Oliver, Preston Thomas, Makita Mikako, Nakatsutsumi Motoaki, Pan Xiayun, Köhler Alexander, Harmand Marion, Toleikis Sven, Falk Katerina, Juha Libor

2024, 9(1) doi: 10.1063/5.0157781

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We report on an experiment performed at the FLASH2 free-electron laser (FEL) aimed at producing warm dense matter via soft x-ray isochoric heating. In the experiment, we focus on study of the ions emitted during the soft x-ray ablation process using time-of-flight electron multipliers and a shifted Maxwell–Boltzmann velocity distribution model. We find that most emitted ions are thermal, but that some impurities chemisorbed on the target surface, such as protons, are accelerated by the electrostatic field created in the plasma by escaped electrons. The morphology of the complex crater structure indicates the presence of several ion groups with varying temperatures. We find that the ion sound velocity is controlled by the ion temperature and show how the ion yield depends on the FEL radiation attenuation length in different materials.

Growth of ablative Rayleigh-Taylor instability induced by time-varying heat-flux perturbation

Liu Yang, Zhang De-Hua, Xin Jing-Fei, Pu Yudong, Li Jun, Tao Tao, Sun Dejun, Yan Rui, Zheng Jian

2024, 9(1) doi: 10.1063/5.0157344

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The evolution of ablative Rayleigh–Taylor instability (ARTI) induced by single-mode stationary and time-varying perturbations in heat flux is studied numerically in two dimensions. Compared with the stationary case, time-varying heat-flux perturbation mitigates ARTI growth because of the enhanced thermal smoothing induced by the wave-like traveling heat flux. A resonance is found to form when the phase velocity of the heat-flux perturbation matches the average sound speed in the ablation region. In the resonant regime, the coherent density and temperature fluctuations enhance the electron thermal conduction in the ablation region and lead to larger ablation pressure and effective acceleration, which consequently yield higher linear growth rate and saturated bubble velocity. The enhanced effective acceleration offers increased implosion velocity but can also compromise the integrity of inertial confinement fusion shells by causing faster ARTI growth.

Design of high-temperature superconductors at moderate pressures by alloying AlH₃ or GaH₃

Liang Xiaowei, Wei Xudong, Zurek Eva, Bergara Aitor, Li Peifang, Gao Guoying, Tian Yongjun

2024, 9(1) doi: 10.1063/5.0159590

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Since the discovery of hydride superconductors, a significant challenge has been to reduce the pressure required for their stabilization. In this context, we propose that alloying could be an effective strategy to achieve this. We focus on a series of alloyed hydrides with the AMH₆ composition, which can be made via alloying A15 AH₃ (A = Al or Ga) with M (M = a group ⅢB or IVB metal), and study their behavior under pressure. Seven of them are predicted to maintain the A15-type structure, similar to AH₃ under pressure, providing a platform for studying the effects of alloying on the stability and superconductivity of AH₃. Among these, the A15-type phases of AlZrH₆ and AlHfH₆ are found to be thermodynamically stable in the pressure ranges of 40–150 and 30–181 GPa, respectively. Furthermore, they remain dynamically stable at even lower pressures, as low as 13 GPa for AlZrH₆ and 6 GPa for AlHfH₆. These pressures are significantly lower than that required for stabilizing A15 AlH₃. Additionally, the introduction of Zr or Hf increases the electronic density of states at the Fermi level compared with AlH₃. This enhancement leads to higher critical temperatures (T_c) of 75 and 76 K for AlZrH₆ and AlHfH₆ at 20 and 10 GPa, respectively. In the case of GaMH₆ alloys, where M represents Sc, Ti, Zr, or Hf, these metals reinforce the stability of the A15-type structure and reduce the lowest thermodynamically stable pressure for GaH₃ from 160 GPa to 116, 95, 80, and 85 GPa, respectively. Particularly noteworthy are the A15-type GaMH₆ alloys, which remain dynamically stable at low pressures of 97, 28, 5, and 6 GPa, simultaneously exhibiting high T_c of 88, 39, 70, and 49 K at 100, 35, 10, and 10 GPa, respectively. Overall, these findings enrich the family of A15-type superconductors and provide insights for the future exploration of high-temperature hydride superconductors that can be stabilized at lower pressures.

2024 Vol. 9, No. 1

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