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1. High deuteron and neutron yields from the interaction of a petawatt laser with a cryogenic deuterium jet

   https://doi.org/10.3389/fphy.2022.964696  

   Jiao, X.; Curry, C. B.; Gauthier, M.; Chou, H.-G. J.; Fiuza, F.; Kim, J. B.; Phan, D. D.; McCary, E.; Galtier, E. C.; Dyer, G. M.; et al (January 2023, Frontiers in Physics)

   A compact high-flux, short-pulse neutron source would have applications from nuclear astrophysics to cancer therapy. Laser-driven neutron sources can achieve fluxes much higher than spallation and reactor neutron sources by reducing the volume and time in which the neutron-producing reactions occur by orders of magnitude. We report progress towards an efficient laser-driven neutron source in experiments with a cryogenic deuterium jet on the Texas Petawatt laser. Neutrons were produced both by laser-accelerated multi-MeV deuterons colliding with Be and mixed metallic catchers and by d ( d , n ) 3 He fusion reactions within the jet. We observed deuteron yields of 10 13 /shot in quasi-Maxwellian distributions carrying ∼ 8 − 10 % of the input laser energy. We obtained neutron yields greater than 10 10 /shot and found indications of a deuteron-deuteron fusion neutron source with high peak flux ( > 1 0 22 cm −2  s −1 ). The estimated fusion neutron yield in our experiment is one order of magnitude higher than any previous laser-induced dd fusion reaction. Though many technical challenges will have to be overcome to convert this proof-of-principle experiment into a consistent ultra-high flux neutron source, the neutron fluxes achieved here suggest laser-driven neutron sources can support laboratory study of the rapid neutron-capture process, which is otherwise thought to occur only in astrophysical sites such as core-collapse supernova, and binary neutron star mergers. 

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2. Physics and applications of dusty plasmas: The Perspectives 2023

   https://doi.org/10.1063/5.0168088  

   Beckers, J.; Berndt, J.; Block, D.; Bonitz, M.; Bruggeman, P. J.; Couëdel, L.; Delzanno, G. L.; Feng, Y.; Gopalakrishnan, R.; Greiner, F.; et al (December 2023, Physics of Plasmas)

   Dusty plasmas are electrically quasi-neutral media that, along with electrons, ions, neutral gas, radiation, and electric and/or magnetic fields, also contain solid or liquid particles with sizes ranging from a few nanometers to a few micrometers. These media can be found in many natural environments as well as in various laboratory setups and industrial applications. As a separate branch of plasma physics, the field of dusty plasma physics was born in the beginning of 1990s at the intersection of the interests of the communities investigating astrophysical and technological plasmas. An additional boost to the development of the field was given by the discovery of plasma crystals leading to a series of microgravity experiments of which the purpose was to investigate generic phenomena in condensed matter physics using strongly coupled complex (dusty) plasmas as model systems. Finally, the field has gained an increasing amount of attention due to its inevitable connection to the development of novel applications ranging from the synthesis of functional nanoparticles to nuclear fusion and from particle sensing and diagnostics to nano-contamination control. The purpose of the present perspectives paper is to identify promising new developments and research directions for the field. As such, dusty plasmas are considered in their entire variety: from classical low-pressure noble-gas dusty discharges to atmospheric pressure plasmas with aerosols and from rarefied astrophysical plasmas to dense plasmas in nuclear fusion devices. Both fundamental and application aspects are covered. 

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3. Strong collisionless coupling between an unmagnetized driver plasma and a magnetized background plasma

   https://doi.org/10.1063/5.0144725  

   Cruz, F. D.; Schaeffer, D. B.; Cruz, F.; Silva, L. O. (May 2023, Physics of Plasmas)

   Fast-exploding plasmas traveling though magnetized, collisionless plasmas can occur in a variety of physical systems, such as supernova remnants, coronal mass ejections, and laser-driven laboratory experiments. To study these systems, it is important to understand the coupling process between the plasmas. In this work, we develop a semi-analytical model of the parameters that characterize the strong collisionless coupling between an unmagnetized driver plasma and a uniformly and perpendicularly magnetized background plasma. In particular, we derive analytical expressions that describe the characteristic diamagnetic cavity and magnetic compression of these systems, such as their corresponding velocities, the compression ratio, and the maximum size of the cavity. The semi-analytical model is compared with collisionless 1D particle-in-cell simulations and experimental results with laser-driven plasmas. The model allows us to provide bounds for parameters that are otherwise difficult to diagnose in experiments with similar setups. 

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4. Simultaneous studies of K- and L-shell mid-atomic-number plasmas produced by Z-pinches

   https://doi.org/10.1088/1361-6587/ad8fd2  

   Stafford, A; Safronova, A S; Kantsyrev, V L; Shlyaptseva, V V (November 2024, Plasma Physics and Controlled Fusion)

   Z-pinches have been intensively studied for their applications to high energy density (HED) physics, x-ray sources, astrophysics, and inertial confinement fusion. Alumel (mostly Ni) double planar wire array (DPWA) Z-pinch experiments were performed on the Zebra generator at the enhanced current of 1.6 MA with an advanced setup of diagnostics to measure the temporal evolution of x-ray radiation from plasmas. The implementation of two time-gated spectrometers which recorded hard and soft x-ray radiation allowed for simultaneous studies of K-shell and L-shell radiating plasmas, respectively, in a single experiment. Two almost identical DPWA experiments established a wide observation window around the main x-ray burst. Overall, time-gated plasma spectroscopy provided more information on temporal evolution of ‘hot’ and ‘cold’ K-shell radiating plasmas compared to slowly evolving L-shell radiating plasma. In addition, new spectral features such as from hollow ions were observed and studied using the time-gated K-shell plasma spectroscopy, which is important for further investigation of exotic ion states in HED plasmas. 

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5. Threshold effects in the 10B(p,α)7Be, 12C(p,γ)13N and 14N(p,γ)15O reactions

   https://doi.org/10.3389/fphy.2022.1009489  

   Wiescher, M.; deBoer, R.J.; Görres, J. (October 2022, Frontiers in Physics)

   The typical energy range for charge particle interactions in stellar plasmas corresponds to a few 10s or 100s of keV. At these low energies, the cross sections are so vanishingly small that they cannot be measured directly with accelerator based experimental techniques. Thus, indirect studies of the compound structure near the threshold are used in the framework of reaction models to complement the direct data in order to extrapolate the cross section into the low energy regime. However, at the extremely small cross sections of interest, there maybe other quantum effects that modify the such extracted cross section. These may result from additional nuclear interactions associated with the threshold itself or could be due to other processes, such as electron screening. Measurements in plasma environments like at the OMEGA or National Ignition Facility facilities offer an entirely new set of experimental conditions for studying these types of reactions, often directly at the energies of interest. In this paper, we examine three reaction, 10 B( p , α ) 7 Be, 12 C( p , γ ) 13 N and 14 N( p , γ ) 15 O, which have all been measured at very low energies using accelerator based methods. All three reactions produce relatively long-lived radioactive nuclei, which can be collected and analyzed at plasma facilities using a variety of collection and identification techniques. 

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