Matter and Radiation at Extremes

X-ray transition and K-edge energies in dense finite-temperature plasmas: Challenges of a generalized approach with spectroscopic precision

Li X., Rosmej F. B.

2025, 10(2) doi: 10.1063/5.0235418

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The capacity to predict X-ray transition and K-edge energies in dense finite-temperature plasmas with high precision is of primary importance for atomic physics of matter under extreme conditions. The dual characteristics of bound and continuum states in dense matter are modeled by a valence-band-like structure in a generalized ion-sphere approach with states that are either bound, free, or mixed. The self-consistent combination of this model with the Dirac wave equations of multielectron bound states allows one to fully respect the Pauli principle and to take into account the exact nonlocal exchange terms. The generalized method allows very high precision without implication of calibration shifts and scaling parameters and therefore has predictive power. This leads to new insights in the analysis of various data. The simple ionization model representing the K-edge is generalized to excitation–ionization phenomena resulting in an advanced interpretation of ionization depression data in near-solid-density plasmas. The model predicts scaling relations along the isoelectronic sequences and the existence of bound M-states that are in excellent agreement with experimental data, whereas other methods have failed. The application to unexplained data from compound materials also gives good agreement without the need to invoke any additional assumptions in the generalized model, whereas other methods have lacked consistency.

Diagnosis of focal spots at relativistic intensity utilizing coherent radiation from laser-driven flying electron sheets

Xu Shirui, Pan Zhuo, Gao Ying, Zhao Jiarui, Chen Shiyou, Mei Zhusong, Chen Xun, Peng Ziyang, Liu Xuan, Liang Yulan, Xu Tianqi, Song Tan, Wu Qingfan, Zhang Yujia, Liu Zhipeng, Zhang Zihao, Chen Haoran, Han Qihang, Shen Jundong, Hua Chenghao, Zhu Kun, Zhao Yanying, Lin Chen, Yan Xueqing, Ma Wenjun

2025, 10(2) doi: 10.1063/5.0255211

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Experimental validation of laser intensity is particularly important for the study of fundamental physics at extremely high intensities. However, reliable diagnosis of the focal spot and peak intensity faces huge challenges. In this work, we demonstrate for the first time that the coherent radiation farfield patterns from laser–foil interactions can serve as an in situ, real-time, and easy-to-implement diagnostic for an ultraintense laser focus. The laser-driven electron sheets, curved by the spatially varying laser field and leaving the targets at nearly the speed of light, produce doughnut-shaped patterns depending on the shapes of the focal spot and the absolute laser intensities. Assisted by particle-in-cell simulations, we can achieve measurements of the intensity and the focal spot, and provide immediate feedback to optimize the focal spots for extremely high intensity.

Currents from relativistic laser-plasma interaction as a novel metrology for the system stability of high-repetition-rate laser secondary sources

Ehret Michael, Vladisavlevici Iuliana-Mariana, Bradford Philip Wykeham, Cikhardt Jakub, Filippov Evgeny, Henares Jose Luis, Martín Rubén Hernández, de Luis Diego, Pérez-Hernández José Antonio, Vicente Pablo, Burian Tomas, García-García Enrique, Hernández Juan, Mendez Cruz, Ruíz Marta Olivar, Varela Óscar, Rodríguez Frías Maria Dolores, Santos João Jorge, Gatti Giancarlo

2025, 10(2) doi: 10.1063/5.0247778

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This work demonstrates experimentally the close relation between return currents from relativistic laser-driven target polarization and the quality of the relativistic laser–plasma interaction for laser-driven secondary sources, taking as an example ion acceleration by target normal sheath acceleration. The Pearson linear correlation of maximum return current amplitude and proton spectrum cutoff energy is found to be in the range from ∼0.70 to 0.94. kA-scale return currents rise in all interaction schemes where targets of any kind are charged by escaping laser-accelerated relativistic electrons. Their precise measurement is demonstrated using an inductive scheme that allows operation at high repetition rates. Thus, return currents can be used as a metrological online tool for the optimization of many laser-driven secondary sources and for diagnosing their stability. In particular, in two parametric studies of laser-driven ion acceleration, we carry out a noninvasive online measurement of return currents in a tape target system irradiated by the 1 PW VEGA-3 laser at Centro de Láseres Pulsados: first, the size of the irradiated area is varied at best compression of the laser pulse; second, the pulse duration is varied by means of induced group delay dispersion at best focus. This work paves the way to the development of feedback systems that operate at the high repetition rates of PW-class lasers.

Commissioning of the 1 PW experimental area at ELI-NP using a short focal parabolic mirror for proton acceleration

Cernaianu M. O., Ghenuche P., Rotaru F., Tudor L., Chalus O., Gheorghiu C., Popescu D. C., Gugiu M., Balascuta S., Magureanu A., Tataru M., Horny V., Corobean B., Dancus I., Alincutei A., Asavei T., Diaconescu B., Dinca L., Dreghici D. B., Ghita D. G., Jalba C., Leca V., Lupu A. M., Nastasa V., Negoita F., Patrascoiu M., Schimbeschi F., Stutman D., Ticos C., Ursescu D., Arefiev A., Tomassini P., Malka V., Gales S., Tanaka K. A., Ur C. A., Doria D.

2025, 10(2) doi: 10.1063/5.0241077

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High-power laser systems have opened new frontiers in scientific research and have revolutionized various scientific fields, offering unprecedented capabilities for understanding fundamental physics and allowing unique applications. This paper details the successful commissioning of the 1 PW experimental area at the Extreme Light Infrastructure–Nuclear Physics (ELI-NP) facility in Romania, using both of the available laser arms. The experimental setup featured a short focal parabolic mirror to accelerate protons through the target normal sheath acceleration mechanism. Detailed experiments were conducted using various metallic and diamond-like carbon targets to investigate the dependence of the proton acceleration on different laser parameters. Furthermore, the paper discusses the critical role of the laser temporal profile in optimizing proton acceleration, supported by hydrodynamic simulations that are correlated with experimental outcomes. The findings underscore the potential of the ELI-NP facility to advance research in laser–plasma physics and contribute significantly to high-energy physics applications. The results of this commissioning establish a strong foundation for experiments by future users.

First observations on wall plasma expansion and x-ray flux in foam hohlraum at 100 kJ laser facility

Zhang Lu, Lin Zhiwei, Jing Longfei, Zheng Jianhua, Wang Qiangqiang, Li Sanwei, Cao Zhurong, Dong Yunsong, Deng Bo, Li Liling, Li Hang, Li Yulong, Du Huabing, Zhan Xiayu, Xu Xibin, Niu Gao, Zhou Wei, Kuang Longyu, Yang Dong, Yang Jiamin, Zhao Zongqing, Ding Yongkun, Zhang Weiyan

2025, 10(2) doi: 10.1063/5.0237908

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The first experiments on laser-driven cylindrical gold foam hohlraums have been performed at the 100 kJ SG-III laser facility. Measurements of the expanding plasma emission show that there is less expanding plasma fill in foam hohlraums with a wall density of 0.8 g/cm³ than in solid gold hohlraums. The radiation temperatures at different angles confirm these results. Simulation results show that the expanding plasma density in the foam hohlraums is lower than in the solid hohlraums, resulting in less expanding plasma emission and higher radiation temperature. Thus, foam gold hohlraums have advantages in reducing wall plasma filling and improving X-ray transmission, which has potential applications in achieving a higher fusion yield.

Single-image super-resolution of gamma-ray imaging system using deep denoiser prior based on plug-and-play framework

Li Guo-Guang, Sheng Liang, Duan Bao-Jun, Li Yang, Song Yan, Zhu Zi-Jian, Yan Wei-Peng, Hei Dong-Wei, Xing Qing-Zi

2025, 10(2) doi: 10.1063/5.0236541

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Gamma-ray imaging systems are powerful tools in radiographic diagnosis. However, the recorded images suffer from degradations such as noise, blurring, and downsampling, consequently failing to meet high-precision diagnostic requirements. In this paper, we propose a novel single-image super-resolution algorithm to enhance the spatial resolution of gamma-ray imaging systems. A mathematical model of the gamma-ray imaging system is established based on maximum a posteriori estimation. Within the plug-and-play framework, the half-quadratic splitting method is employed to decouple the data fidelity term and the regularization term. An image denoiser using convolutional neural networks is adopted as an implicit image prior, referred to as a deep denoiser prior, eliminating the need to explicitly design a regularization term. Furthermore, the impact of the image boundary condition on reconstruction results is considered, and a method for estimating image boundaries is introduced. The results show that the proposed algorithm can effectively addresses boundary artifacts. By increasing the pixel number of the reconstructed images, the proposed algorithm is capable of recovering more details. Notably, in both simulation and real experiments, the proposed algorithm is demonstrated to achieve subpixel resolution, surpassing the Nyquist sampling limit determined by the camera pixel size.

Effect of laser wavelength on growth of ablative Rayleigh–Taylor instability in inertial confinement fusion

Lu Zhantao, Xie Xinglong, Liang Xiao, Sun Meizhi, Zhu Ping, Zhang Xuejie, Li Linjun, Xue Hao, Zhang Guoli, Haq Rashid Ul, Zhang Dongjun, Zhu Jianqiang

2025, 10(2) doi: 10.1063/5.0235138

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The effect of drive laser wavelength on the growth of ablative Rayleigh–Taylor instability (ARTI) in inertial confinement fusion (ICF) is studied with two-dimensional numerical simulations. The results show that in the plasma acceleration phase, shorter wavelengths lead to more efficient coupling between the laser and the kinetic energy of the implosion fluid. Under the condition that the laser energy coupled to the implosion fluid is constant, the ARTI growth rate decreases as the laser wavelength moves toward the extreme ultraviolet band, reaching its minimum value near λ = 65 nm, and when the laser wavelength continuously moves toward the X-ray band, the ARTI growth rate increases rapidly. It is found that the results deviate from the theoretical ARTI growth rate. As the laser intensity benchmark increases, the position of the minimum ARTI growth rate shifts toward shorter wavelengths. As the initial sinusoidal perturbation wavenumber decreases, the position of the minimum ARTI growth rate shifts toward longer wavelengths. We believe that the conclusions drawn from the present simulations and analysis will help provide a better understanding of the ICF process and improve the theory of ARTI growth.

Investigations of key issues on the reproducibility of high-T_c superconductivity emerging from compressed La₃Ni₂O₇

Zhou Yazhou, Guo Jing, Cai Shu, Sun Hualei, Li Chengyu, Zhao Jinyu, Wang Pengyu, Han Jinyu, Chen Xintian, Chen Yongjin, Wu Qi, Ding Yang, Xiang Tao, Mao Ho-kwang, Sun Liling

2025, 10(2) doi: 10.1063/5.0247684

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Signatures of superconductivity near 80 K have recently been discovered in single crystals of La₃Ni₂O₇ under pressure, which makes it a new candidate for high-temperature superconductors dominated by 3d transition elements, following the cuprate and iron-pnictide superconductors. However, there are several critical questions that have been perplexing the scientific community: (1) What factors contribute to the inconsistent reproducibility of the experimental results? (2) What is the fundamental nature of pressure-induced superconductivity: bulk or nonbulk (filamentary-like)? (3) Where is the superconducting phase located within the sample if it is filamentary-like? (4) Is the oxygen content important for the development and stabilization of superconductivity? In this study, we employ comprehensive high-pressure techniques to address these questions. Through our modulated ac susceptibility measurements, we are the first to find that the superconductivity in this nickelate is filamentary-like. Our scanning transmission electron microscopy investigations suggest that the filamentary-like superconductivity most likely emerges at the interface between La₃Ni₂O₇ and La₄Ni₃O₁₀ phases. By tuning the oxygen content of polycrystalline La₃Ni₂O₇, we also find that it plays vital role in the development and stabilization of superconductivity in this material. The upper and lower bounds on the oxygen content are 7.35 and 6.89, respectively. Our results provide not only new insights into the puzzling issues regarding this material, but also significant information that will enable a better understanding of its superconductivity.

Leading role of satellite interstitial electrons in superconductivity in ternary superlithide Li₁₄CP

Liu Yan, Cui Tian, Li Da

2025, 10(2) doi: 10.1063/5.0252519

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The discovery of pressure-induced superconducting electrides has sparked a intense wave of interest in novel superconductors. However, opinions vary regarding the relationship between non-nuclear attractors (NNAs) and superconductivity, with two opposing views currently represented by the materials Li₆P and Li₆C. Here, we choose the ternary Li–C–P as a model system and reveal the underlying mechanism by which NNAs contribute to superconductivity. The loosely bound NNAs in the superlithide Li₁₄CP covalently bond with Li and form unique satellite interstitial electrons (SIEs) around Li near the Fermi level, dominating the superconductivity. First-principles calculations show that the SIEs progressively increase in number and couple strongly with phonons at high pressure. Moreover, the Fermi surface nesting associated with SIEs induces phonon softening, further enhancing the electron–phonon coupling and giving the superlithide Li₁₄CP a T_c of 10.6 K at 300 GPa. The leading role of SIEs in superconductivity is a general one and is also relevant to the recently predicted Li₆P and Li₆C. Our work presented here reshapes the understanding of NNA-dominated superconductivity and holds promise for guiding future discoveries and designs of novel high-temperature superconductors.

Erratum: “Enhanced ion acceleration using the high-energy petawatt PETAL laser” [Matter Radiat. Extremes 6, 056901 (2021)]

Raffestin D., Lecherbourg L., Lantuéjoul I., Vauzour B., Masson-Laborde P. E., Davoine X., Blanchot N., Dubois J. L., Vaisseau X., d’Humières E., Gremillet L., Duval A., Reverdin Ch., Rosse B., Boutoux G., Ducret J. E., Rousseaux Ch., Tikhonchuk V., Batani D.

2025, 10(2) doi: 10.1063/5.0253622

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2025 Vol. 10, No. 2

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Current Issue 2025 Vol. 10, No. 2

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Current Issue
2025 Vol. 10, No. 2