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Keywords = laser plasma electron acceleration

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15 pages, 10319 KB  
Article
S-Band Klystron Intra-Pulse Phase Feedback Upgrade at SPARC_LAB Facility
by Xianghe Fang, Marco Bellaveglia, Alessandro Gallo, Riccardo Magnanimi, Andrea Michelotti, Sergio Quaglia, Michele Scampati, Giorgio Scarselletta, Beatrice Serenellini, Simone Tocci and Luca Piersanti
Appl. Sci. 2026, 16(12), 5733; https://doi.org/10.3390/app16125733 - 6 Jun 2026
Viewed by 200
Abstract
One of the main technological challenges in plasma wakefield acceleration (PWFA) research and development is achieving stable and reproducible acceleration. In particular, for PWFA schemes based on particle-driven plasma wave excitation, beam stability and timing jitter are increasingly critical. In these configurations, magnetic [...] Read more.
One of the main technological challenges in plasma wakefield acceleration (PWFA) research and development is achieving stable and reproducible acceleration. In particular, for PWFA schemes based on particle-driven plasma wave excitation, beam stability and timing jitter are increasingly critical. In these configurations, magnetic or radio-frequency (RF) compression schemes are often used, and the beam time-of-arrival jitter at the end of the linear accelerator can be strongly correlated with the phase noise of RF accelerating structures operated off-crest. For this reason, since 2008, an RF phase fast-feedback system acting within each RF pulse has been successfully implemented at Laboratori Nazionali di Frascati, Istituto Nazionale di Fisica Nucleare (LNF-INFN) at the Sources for Plasma Accelerators and Radiation Compton with Laser And Beam (SPARC_LAB) facility, operating on both S-band (2.856 GHz) and C-band (5.712 GHz) klystrons. This paper presents the upgrade and optimization of the fast-feedback system for an S-band klystron powered by a pulse-forming network modulator. This technology introduces significantly higher intrinsic phase noise than, for instance, solid state-based modulators. It is therefore essential to minimize such phase fluctuations to keep the machine stability under control. Both the feedback hardware (electronic boards and RF circuitry) and the software (controller and user interface) have been upgraded. Tests performed at SPARC_LAB achieved a reduction in klystron-induced jitter of a factor of 30, reaching values below 15 fs rms on both power plants. Moreover, adding a remote control of the feedback loop enabled a straightforward optimization of the operating point, allowing the phase stability performance to be pushed close to its practical limits. A detailed analysis of RF phase noise measurements with the fast-feedback loop in operation is also presented. Full article
(This article belongs to the Special Issue New Challenges in Plasma Accelerators)
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19 pages, 2582 KB  
Article
Betatron Radiation as a Path to Plasma Undulators: A Case Study at SPARC_LAB
by Alessandro Curcio, Angelo Biagioni, Alessandro Cianchi, Gemma Costa, Lucio Crincoli, Alessio Del Dotto, Romain Demitra, Massimo Ferrario, Andrea Frazzitta, Mario Galletti, Andrea Mostacci, Riccardo Pompili, Andrea Renato Rossi, Livio Verra and Enrica Chiadroni
Appl. Sci. 2026, 16(10), 4950; https://doi.org/10.3390/app16104950 - 15 May 2026
Viewed by 293
Abstract
Nowadays, there is a deep interest in developing more compact user facilities, and plasma technology is one of the most promising techniques, not only for acceleration modules, but also for what is ancillary to the delivery of radiation to users, such as free [...] Read more.
Nowadays, there is a deep interest in developing more compact user facilities, and plasma technology is one of the most promising techniques, not only for acceleration modules, but also for what is ancillary to the delivery of radiation to users, such as free electron lasers. In this regard, significant efforts have been made to miniaturize diagnostic stations, detection devices, and transfer lines, e.g., based on active plasma lenses. However, conventional undulators are still too cumbersome and expensive to meet the requirements of compactness and sustainability. For the aforementioned reasons, advanced undulator concepts have aroused great interest in pushing the frontier beyond conventional, magnet-based undulators. In this regard, a promising, very compact alternative is the use of the betatron motion of electrons in an ion channel to emulate an undulator device. This paper reports a feasibility study aiming to develop plasma-based undulator devices at SPARC_LAB as the test facility of the EuPRAXIA@SPARC_LAB project. In particular, this work provides a systematic assessment of free-electron-laser amplification in a plasma ion-channel undulator under experimentally realistic beam parameters, delivering quantitative predictions for gain and radiation performance in this configuration. Full article
(This article belongs to the Section Optics and Lasers)
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20 pages, 6703 KB  
Article
Laser Wakefield Electron Acceleration in a Periodically Modulated Plasma Density Profile
by Rareș Iovănescu, Radu P. Daia, Anana C. Gîrlea, Emil I. Slușanschi and Cătălin M. Ticoș
Plasma 2026, 9(2), 12; https://doi.org/10.3390/plasma9020012 - 29 Apr 2026
Viewed by 662
Abstract
We investigate laser wakefield electron acceleration in a periodic plasma density profile using 2D PIC simulations with the EPOCH code. The profile of the electron density has the form [...] Read more.
We investigate laser wakefield electron acceleration in a periodic plasma density profile using 2D PIC simulations with the EPOCH code. The profile of the electron density has the form n(x)=n01+δsin2πx/x0, where n0 is the steady electron density, x0=100m is the spatial periodicity in the laser propagation direction and δ, taking the values 0, 0.1, 0.3, 0.5 and 0.7, is the modulation parameter. The bubble size varies with the modulated plasma density, thereby influencing the electron acceleration, which occurs within a continuously changing bubble structure. We propose an analytical model to estimate the energies of the accelerated electrons, and evaluate the maximum electron energies at 500 fs intervals for the five modulated density profiles. We then calculate the dephasing and depletion lengths for these modulated plasma profiles and examine their dependence on δ. The results show a growth in both lengths with δ, with depletion being the main limitation in these cases. Additionally, we compute and compare the transverse emittance of the self-injected electron bunches corresponding to the various density profiles at the same simulation time, and other characteristics, like the center energy and energy spread. Emittance is observed to experience a decrease with the increase in the modulation parameter. Full article
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19 pages, 4742 KB  
Article
AI-Assisted Bibliometric Analysis of LWFA Research: Trends and Future Directions
by Mehdi Abedi-Varaki and Gediminas Račiukaitis
Appl. Sci. 2026, 16(5), 2335; https://doi.org/10.3390/app16052335 - 27 Feb 2026
Viewed by 800
Abstract
This study employs a comprehensive bibliometric analysis to map the global scientific landscape of laser wakefield acceleration (LWFA) from 1990 to 2025. Using data extracted from the Web of Science (WoS) and analyzed with Bibliometrix, VOSviewer, and CiteSpace, the study identifies key publication [...] Read more.
This study employs a comprehensive bibliometric analysis to map the global scientific landscape of laser wakefield acceleration (LWFA) from 1990 to 2025. Using data extracted from the Web of Science (WoS) and analyzed with Bibliometrix, VOSviewer, and CiteSpace, the study identifies key publication trends, influential authors, leading countries, prominent journals, and thematic evolution within the field. The findings reveal exponential growth in LWFA-related research, driven by advances in high-power laser technology and controlled injection techniques. Network analyses demonstrate extensive international collaboration and a strong interdisciplinary structure linking plasma physics, optics, and accelerator science. Keyword co-occurrence and burst analyses highlight emerging topics such as ionization injection, dual-stage acceleration, betatron radiation, and machine learning-assisted optimization. These insights delineate both the historical progression and the dynamic frontiers of LWFA, providing a systematic understanding of its development and guiding future research toward the realization of compact, high-quality electron sources and next-generation plasma-based accelerators. Full article
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13 pages, 12795 KB  
Article
Validation of a Compact and Tunable Continuous Gas-Flow Laser-Plasma Target for Electron Beam Production Above 150 MeV
by Pierre Drobniak, Jana Serhal, Maria Pia Anania, Elsa Baynard, Arnaud Beck, Christelle Bruni, Antoine Cauchois, Gemma Costa, Lucio Crincoli, Denis Douillet, Julien Gautier, Jean-Philippe Goddet, Coline Guyot, Gregory Iaquaniello, Gueladio Kane, Sophie Kazamias, Olena Kononenko, Viacheslav Kubytskyi, Bruno Lucas, Ali Mahjoub, Antoine Maitrallain, Olivier Neveu, Yann Peinaud, Moana Pittman, Pascal Rousseau, Johan Sebastián Ramírez Amado, Arnd Specka, Cédric Thaury and Kevin Cassouadd Show full author list remove Hide full author list
Appl. Sci. 2026, 16(5), 2312; https://doi.org/10.3390/app16052312 - 27 Feb 2026
Cited by 1 | Viewed by 567
Abstract
The present article reports on the generation of stable 50 pC low-divergence electron beams above 150 MeV from laser-driven wakefield acceleration using a continuous-flow gas target prototype tested at the 60 TW Salle Jaune facility at LOA. The gas target design is meant [...] Read more.
The present article reports on the generation of stable 50 pC low-divergence electron beams above 150 MeV from laser-driven wakefield acceleration using a continuous-flow gas target prototype tested at the 60 TW Salle Jaune facility at LOA. The gas target design is meant to be easily transported and integrated as an element of the beamline with a differential pumping system offering some 10−4 mbar pressure in the rest of the line. A dedicated gas injection system allows for the control of the gas mixture concentration and gas pressure in two different regions of the target within the frame of controlled ionisation injection schemes. The measured electron beam parameters show the importance of gas density profiles and longitudinal gas mixture confinement. Full article
(This article belongs to the Special Issue Trends and Prospects in Laser–Plasma Accelerator)
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20 pages, 6994 KB  
Article
Design of Spectrometer Energy Measurement Setups for the Future EuPRAXIA@SPARC_LAB and SSRIP Linacs
by Danilo Quartullo, David Alesini, Alessandro Cianchi, Francesco Demurtas, Luigi Faillace, Giovanni Franzini, Andrea Ghigo, Anna Giribono, Riccardo Pompili, Lucia Sabbatini, Angelo Stella, Cristina Vaccarezza, Alessandro Vannozzi and Livio Verra
Instruments 2025, 9(4), 34; https://doi.org/10.3390/instruments9040034 - 17 Dec 2025
Viewed by 720
Abstract
EuPRAXIA@SPARC_LAB is an FEL (Free-Electron Laser) user facility currently under construction at INFN-LNF in the framework of the EuPRAXIA collaboration. The electron beam will be accelerated to 1 GeV by an X-band RF linac followed by a plasma wakefield acceleration stage. This high-brightness [...] Read more.
EuPRAXIA@SPARC_LAB is an FEL (Free-Electron Laser) user facility currently under construction at INFN-LNF in the framework of the EuPRAXIA collaboration. The electron beam will be accelerated to 1 GeV by an X-band RF linac followed by a plasma wakefield acceleration stage. This high-brightness linac requires diagnostic devices able to measure the beam parameters with high accuracy and resolution. To monitor the beam energy and its spread, magnetic dipoles and quadrupoles will be installed along the linac, in combination with viewing screens and CMOS cameras. Macroparticle beam dynamics simulations have been performed to determine the optimal energy measurement setup in terms of accuracy and resolution. Similar diagnostics evaluations have been carried out for the spectrometer installed at the 100 MeV RF linac of the radioactive beam facility SSRIP (IFIN-HH, Romania), whose commissioning, foreseen for 2026, will be performed by INFN-LNF in collaboration with IFIN-HH. Optics measurements have been performed to characterize the resolution and magnification of the optical system that will be used at SSRIP, and probably also at EuPRAXIA@SPARC_LAB, for beam energy monitoring. Full article
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13 pages, 1037 KB  
Article
Real-Time Dose Monitoring via Non-Destructive Charge Measurement of Laser-Driven Electrons for Medical Applications
by David Gregocki, Petra Köster, Luca Umberto Labate, Simona Piccinini, Federico Avella, Federica Baffigi, Gabriele Bandini, Fernando Brandi, Lorenzo Fulgentini, Daniele Palla, Martina Salvadori, Simon Gerasimos Vlachos and Leonida Antonio Gizzi
Instruments 2025, 9(4), 25; https://doi.org/10.3390/instruments9040025 - 23 Oct 2025
Cited by 1 | Viewed by 1889
Abstract
Laser-accelerated electron beams, in the so-called Very High-Energy Electron (VHEE) energy range, are of great interest for biomedical applications. For instance, laser-driven VHEE beams are envisaged to offer suitable compact accelerators for the promising field of FLASH radiotherapy. Radiobiology experiments carried out using [...] Read more.
Laser-accelerated electron beams, in the so-called Very High-Energy Electron (VHEE) energy range, are of great interest for biomedical applications. For instance, laser-driven VHEE beams are envisaged to offer suitable compact accelerators for the promising field of FLASH radiotherapy. Radiobiology experiments carried out using laser-driven beams require the real-time knowledge of the dose delivered to the sample. We have developed an online dose monitoring procedure, using an Integrating Current Transformer (ICT) coupled to a suitable collimator, that allows the estimation of the delivered dose on a shot-to-shot basis under suitable assumptions. The cross-calibration of the measured charge with standard offline dosimetry measurements carried out with RadioChromic Films (RCFs) is discussed, demonstrating excellent correlation between the two measurements. Full article
(This article belongs to the Special Issue Plasma Accelerator Technologies)
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23 pages, 4826 KB  
Article
Visualization of High-Intensity Laser–Matter Interactions in Virtual Reality and Web Browser
by Martin Matys, James P. Thistlewood, Mariana Kecová, Petr Valenta, Martina Greplová Žáková, Martin Jirka, Prokopis Hadjisolomou, Alžběta Špádová, Marcel Lamač and Sergei V. Bulanov
Photonics 2025, 12(5), 436; https://doi.org/10.3390/photonics12050436 - 30 Apr 2025
Cited by 3 | Viewed by 4683
Abstract
We present the Virtual Beamline (VBL) application, an interactive web-based platform for visualizing high-intensity laser–matter interactions using particle-in-cell (PIC) simulations, with future potential for experimental data visualization. These interactions include ion acceleration, electron acceleration, γ-flash generation, electron–positron pair production, and attosecond and [...] Read more.
We present the Virtual Beamline (VBL) application, an interactive web-based platform for visualizing high-intensity laser–matter interactions using particle-in-cell (PIC) simulations, with future potential for experimental data visualization. These interactions include ion acceleration, electron acceleration, γ-flash generation, electron–positron pair production, and attosecond and spiral pulse generation. Developed at the ELI Beamlines facility, VBL integrates a custom-built WebGL engine with WebXR-based Virtual Reality (VR) support, allowing users to explore complex plasma dynamics in non-VR mode on a computer screen or in fully immersive VR mode using a head-mounted display. The application runs directly in a standard web browser, ensuring broad accessibility. VBL enhances the visualization of PIC simulations by efficiently processing and rendering four main data types: point particles, 1D lines, 2D textures, and 3D volumes. By utilizing interactive 3D visualization, it overcomes the limitations of traditional 2D representations, offering enhanced spatial understanding and real-time manipulation of visualization parameters such as time steps, data layers, and colormaps. Users can interactively explore the visualized data by moving their body or using a controller for navigation, zooming, and rotation. These interactive capabilities improve data exploration and interpretation, making VBL a valuable tool for both scientific analysis and educational outreach. The visualizations are hosted online and freely accessible on our server, providing researchers, the general public, and broader audiences with an interactive tool to explore complex plasma physics simulations. By offering an intuitive and dynamic approach to large-scale datasets, VBL enhances both scientific research and knowledge dissemination in high-intensity laser–matter physics. Full article
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3 pages, 145 KB  
Editorial
Novel Radiation Facilities Based on Plasma Acceleration: The Future of Free Electron Lasers
by Marcello Coreno, Massimo Ferrario, Augusto Marcelli and Francesco Stellato
Condens. Matter 2025, 10(2), 25; https://doi.org/10.3390/condmat10020025 - 27 Apr 2025
Cited by 1 | Viewed by 1153
Abstract
Exploiting acceleration gradients that are up to three orders of magnitude higher than those achievable using conventional radiofrequency-based devices, plasma-based devices promise a revolution in particle acceleration, enabling particles to reach high energies over much shorter distances than existing accelerators [...] Full article
42 pages, 5853 KB  
Review
Harnessing Ultra-Intense Long-Wave Infrared Lasers: New Frontiers in Fundamental and Applied Research
by Igor V. Pogorelsky and Mikhail N. Polyanskiy
Photonics 2025, 12(3), 221; https://doi.org/10.3390/photonics12030221 - 28 Feb 2025
Cited by 4 | Viewed by 3872 | Correction
Abstract
This review explores two main topics: the state-of-the-art and emerging capabilities of high-peak-power, ultrafast (picosecond and femtosecond) long-wave infrared (LWIR) laser technology based on CO2 gas laser amplifiers, and the current and advanced scientific applications of this laser class. The discussion is [...] Read more.
This review explores two main topics: the state-of-the-art and emerging capabilities of high-peak-power, ultrafast (picosecond and femtosecond) long-wave infrared (LWIR) laser technology based on CO2 gas laser amplifiers, and the current and advanced scientific applications of this laser class. The discussion is grounded in expertise gained at the Accelerator Test Facility (ATF) of Brookhaven National Laboratory (BNL), a leading center for ultrafast, high-power CO2 laser development and a National User Facility with a strong track record in high-intensity physics experiments. We begin by reviewing the status of 9–10 μm CO2 laser technology and its applications, before exploring potential breakthroughs, including the realization of 100 terawatt femtosecond pulses. These advancements will drive ongoing research in electron and ion acceleration in plasma, along with applications in secondary radiation sources and atmospheric energy transport. Throughout the review, we highlight how wavelength scaling of physical effects enhances the capabilities of ultra-intense lasers in the LWIR spectrum, expanding the frontiers of both fundamental and applied science. Full article
(This article belongs to the Special Issue High-Power Ultrafast Lasers: Development and Applications)
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9 pages, 373 KB  
Article
Model for Proton Acceleration in Strongly Self-Magnetized Sheath Produced by Ultra-High-Intensity Sub-Picosecond Laser Pulses
by Artem V. Korzhimanov
Quantum Beam Sci. 2025, 9(1), 4; https://doi.org/10.3390/qubs9010004 - 20 Jan 2025
Viewed by 2279
Abstract
Recently, it has been experimentally shown that the sheath acceleration of protons from ultra-thin metal targets irradiated by sub-picosecond laser pulses of intensities above 1021 W/cm2 is suppressed compared to well-established models. This detrimental effect has been attributed to a self-generation [...] Read more.
Recently, it has been experimentally shown that the sheath acceleration of protons from ultra-thin metal targets irradiated by sub-picosecond laser pulses of intensities above 1021 W/cm2 is suppressed compared to well-established models. This detrimental effect has been attributed to a self-generation of gigagauss-level quasi-static magnetic fields in expanded plasmas on the rear side of a target. Here we present a set of numerical simulations which support this statement. Based on 2D full-scale PIC simulations, it is shown that the scaling of a cutoff energy of the accelerated protons with intensity deviates from a well-established Mora model for laser pulses with a duration exceeding 500 fs. This deviation is showed to be connected to effective magnetization of the hottest electrons producing at the maximum of the laser pulse intensity. We propose a modification of the Mora model which incorporates the effect of the possible electron magnetization. Comparing it to the simulation results shows that by appropriately choosing a single fitting parameter, the model produces results that quantitatively coincide with simulations. Full article
(This article belongs to the Special Issue Laser-Assisted Facilities)
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16 pages, 861 KB  
Article
Theoretical Study of the Pre-Plasma Density Scale Length’s Influence on the Absorption Efficiency in Laser–Solid Interaction at Relativistic Laser Intensities for PW-Class Lasers
by Iuliana-Mariana Vladisavlevici, Michael Ehret, Evgeny Filippov, Enrique García-García, Cruz Mendez, Marta Olivar Ruíz, Óscar Varela, Luca Volpe and Jose Antonio Pérez-Hernández
Photonics 2025, 12(1), 71; https://doi.org/10.3390/photonics12010071 - 15 Jan 2025
Cited by 3 | Viewed by 4089
Abstract
This work studied the pre-plasma that builds up in interactions of focused high-power PW-class lasers with solid targets at the target surface facing the laser beam, and its impact on the global laser absorption efficiency as well as on the spectral cut-off energy [...] Read more.
This work studied the pre-plasma that builds up in interactions of focused high-power PW-class lasers with solid targets at the target surface facing the laser beam, and its impact on the global laser absorption efficiency as well as on the spectral cut-off energy of laser-generated proton beams. Our practical heuristic estimates were derived from the example of the VEGA-3 laser at CLPU. Our modeling results for the pre-plasma expansion due to the laser pedestal of VEGA-3 were benchmarked by hydrodynamic simulations, revealing good agreement for the evolution before the arrival of the main Gaussian laser intensity peak. Our detailed numerical two-dimensional Particle-in-Cell simulations showed the impact of different pre-plasma scale lengths on the absorption efficiency of laser energy into electrons, relevant for the seeding of other types of radiation. It was shown that the absorption can increase manyfold when increasing the pre-plasma scale length. This effect can be beneficial for the spectral cut-off energy of accelerated protons, where a trade-off between absorption and electron dynamics yields an optimum pre-plasma scale length. The findings can be applied to other PW-class laser facilities. Full article
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15 pages, 5042 KB  
Article
Characterization of kHz Repetition Rate Laser-Driven Electron Beams by an Inhomogeneous Field Dipole Magnet Spectrometer
by Illia Zymak, Marco Favetta, Gabriele Maria Grittani, Carlo Maria Lazzarini, Gianfranco Tassielli, Annika Grenfell, Leonardo Goncalves, Sebastian Lorenz, Vanda Sluková, Filip Vitha, Roberto Versaci, Edwin Chacon-Golcher, Michal Nevrkla, Jiří Šišma, Roman Antipenkov, Václav Šobr, Wojciech Szuba, Theresa Staufer, Florian Grüner, Loredana Lapadula, Ezio Ranieri, Michele Piombino, Nasr A. M. Hafz, Christos Kamperidis, Daniel Papp, Sudipta Mondal, Pavel Bakule and Sergei V. Bulanovadd Show full author list remove Hide full author list
Photonics 2024, 11(12), 1208; https://doi.org/10.3390/photonics11121208 - 23 Dec 2024
Cited by 5 | Viewed by 3078
Abstract
We demonstrate a method to characterize the beam energy, transverse profile, charge, and dose of a pulsed electron beam generated by a 1 kHz TW laser-plasma accelerator. The method is based on imaging with a scintillating screen in an inhomogeneous, orthogonal magnetic field [...] Read more.
We demonstrate a method to characterize the beam energy, transverse profile, charge, and dose of a pulsed electron beam generated by a 1 kHz TW laser-plasma accelerator. The method is based on imaging with a scintillating screen in an inhomogeneous, orthogonal magnetic field produced by a wide-gap magnetic dipole. Numerical simulations were developed to reconstruct the electron beam parameters accurately. The method has been experimentally verified and calibrated using a medical LINAC. The energy measurement accuracy in the 6–20 MeV range is proven to be better than 10%. The radiation dose has been calibrated by a water-equivalent phantom, RW3, showing a linear response of the method within 2% in the 0.05–0.5 mGy/pulse range. Full article
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18 pages, 8548 KB  
Article
High-Volume Phosphogypsum Cement Stabilized Road Base: Preparation Methods and Strength Formation Mechanism
by Meng Zou, Zhaoyi He, Yuhua Xia, Qinghai Li, Qiwen Yao and Dongwei Cao
Materials 2024, 17(24), 6201; https://doi.org/10.3390/ma17246201 - 19 Dec 2024
Cited by 8 | Viewed by 2171
Abstract
This study investigated the potential for efficient and resourceful utilization of phosphogypsum (PG) through the preparation of a High-volume Phosphogypsum Cement Stabilized Road Base (HPG-CSSB). The investigation analyzed the unconfined compressive strength (UCS), water stability, strength formation mechanism, microstructure, and pollutant curing mechanism [...] Read more.
This study investigated the potential for efficient and resourceful utilization of phosphogypsum (PG) through the preparation of a High-volume Phosphogypsum Cement Stabilized Road Base (HPG-CSSB). The investigation analyzed the unconfined compressive strength (UCS), water stability, strength formation mechanism, microstructure, and pollutant curing mechanism of HPG-CSSB by laser diffraction methods (LD), X-ray diffraction (XRD), fourier-transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDS), and inductively coupled plasma-mass spectrometry (ICP-MS). The optimal mix ratio of HPG-CSSB was 4% cement, 1% CA2, 35% PG, and 60% graded crushed stone. The UCS reached 6.6 MPa, 9.3 MPa, and 11.3 MPa at 7, 28, and 60 d, respectively. The alkaline curing agent stimulated cement activity and accelerated the release of Ca2+ and SO42− from the PG. This formed many C-S-H gels and ettringite (AFt). The curing agent converted Ca2+ to C-(A)-S-H gels due to high volcanic ash activity. The diverse hydration products strengthened HPG-CSSB. The HPG-CSSB exhibits favorable water stability, demonstrating a mere 7.6% reduction in strength following 28 d of immersion. The C-S-H gel and AFt generated in the system can carry out ion exchange and adsorption precipitation with F and PO43− in PG, achieving the curing effect of toxic and hazardous substances. HPG-CSSB meets the Class A standard for integrated wastewater discharge. Full article
(This article belongs to the Special Issue Environmentally Friendly Composites Incorporating Waste Materials)
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9 pages, 1950 KB  
Article
PIC Simulation of Enhanced Electron Acceleration in a Double Nozzle Gas Target Using Spatial–Temporal Coupling with Axiparabola Optics
by Valdas Girdauskas, Vidmantas Tomkus, Mehdi Abedi-Varaki and Gediminas Račiukaitis
Appl. Sci. 2024, 14(22), 10611; https://doi.org/10.3390/app142210611 - 18 Nov 2024
Cited by 3 | Viewed by 1427
Abstract
In this paper, the results of a Particle-in-Cell (PIC) simulation of electrons accelerated using a 10 fs Top-hat (TH) beam with a limited pulse energy of 85 mJ, focused on a double nozzle gas target using an off-axis parabola (OAP), an axiparabola (AXP), [...] Read more.
In this paper, the results of a Particle-in-Cell (PIC) simulation of electrons accelerated using a 10 fs Top-hat (TH) beam with a limited pulse energy of 85 mJ, focused on a double nozzle gas target using an off-axis parabola (OAP), an axiparabola (AXP), and an axiparabola with additional spatial–temporal coupling (AXP+STC), are discussed. The energy of accelerated electrons was predominantly determined through self-focusing and the ionisation injection effects of the laser beam propagating in plasma. The maximal energy of electrons accelerated using an AXP+STC could be higher by 12% compared to the energy of electrons accelerated by the regular OAP. Full article
(This article belongs to the Special Issue Advances of Laser Technologies and Their Applications)
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