Your search keyword '"Target Normal Sheath Acceleration"' showing total 14 results

1. Accelerated protons with energies up to 70 MeV based on the optimized SG-II Peta-watt laser facility

Author

H. H. An, W. Wang, J. Xiong, C. Wang, X. Pan, X. P. Ouyang, S. Jiang, Z. Y. Xie, P. P. Wang, Y. L. Yao, N. Hua, Y. Wang, Z. C. Jiang, Q. Xiao, F. C. Ding, Y. T. Wan, X. Liu, R. R. Wang, Z. H. Fang, P. Q. Yang, Y. E. Jiang, P. Z. Zhang, B. Q. Zhu, J. R. Sun, B. Qiao, A. L. Lei, and J. Q. Zhu

Subjects

laser-driven proton acceleration, SG-II Peta-watt laser, target normal sheath acceleration, Applied optics. Photonics, TA1501-1820

Abstract

The target backsheath field acceleration mechanism is one of the main mechanisms of laser-driven proton acceleration (LDPA) and strongly depends on the comprehensive performance of the ultrashort ultra-intense lasers used as the driving sources. The successful use of the SG-II Peta-watt (SG-II PW) laser facility for LDPA and its applications in radiographic diagnoses have been manifested by the good performance of the SG-II PW facility. Recently, the SG-II PW laser facility has undergone extensive maintenance and a comprehensive technical upgrade in terms of the seed source, laser contrast and terminal focus. LDPA experiments were performed using the maintained SG-II PW laser beam, and the highest cutoff energy of the proton beam was obviously increased. Accordingly, a double-film target structure was used, and the maximum cutoff energy of the proton beam was up to 70 MeV. These results demonstrate that the comprehensive performance of the SG-II PW laser facility was improved significantly.

Published

2023

2. Enhanced Proton Acceleration from Laser Interaction with a Tailored Nanowire Target.

Author

Chao, Yue, Cao, Lihua, Zheng, Chunyang, Liu, Zhanjun, and He, Xiantu

Subjects

NANOWIRES, PROTONS, LASERS, LASER-plasma interactions, LASER pulses

Abstract

Target normal sheath field acceleration via laser interaction with structured solid targets has been widely studied for its potential use in a wide range of applications. Here, a novel nanowire target with a corrugated front surface is proposed to improve the proton acceleration by a target normal sheath field. Two-dimensional particle-in-cell simulations demonstrated that with the existence of the corrugated surface, the cut-off energy of accelerated protons nearly doubles compared to the planar nanowire target. When interacting with the corrugated surface, the incident laser pulse is reflected multiple times, focused and reinforced in each cavity near the front surface, which leads to suppression of the reflectivity and an improvement in the absorption rate. Electrons are heated more efficiently and the sheath field at the target rear side is naturally enhanced. To further investigate the performance of this novel target, a series of simulations with various laser intensities and target sizes were also carried out. This simple target design may provide insights for experiments in the future and should arouse interest because of its wide application. [ABSTRACT FROM AUTHOR]

Published

2022

3. Mapping non-laminar proton acceleration in laser-driven target normal sheath field.

Author

Qin, C. Y., Zhang, H., Li, S., Zhai, S. H., Li, A. X., Qian, J. Y., Gui, J. Y., Wu, F. X., Zhang, Z. X., Xu, Y., Liang, X. Y., Leng, Y. X., Shen, B. F., Ji, L. L., and Li, R. X.

Subjects

*PROTONS, *ELECTRIC fields, *ELECTRIC currents, *BALANCE of payments, *MAGNETIC fields, *RADIOSTEREOMETRY

Abstract

We report on experimental observation of non-laminar proton acceleration modulated by a strong magnetic field in laser irradiating micrometer aluminum targets. The results illustrate the coexistence of ring-like and filamentation structures. We implement the knife edge method into the radiochromic film detector to map the accelerated beams, measuring a source size of 30–110 μm for protons of more than 5 MeV. The diagnosis reveals that the ring-like profile originates from low-energy protons far off the axis whereas the filamentation is from the near-axis high-energy protons, exhibiting non-laminar features. Particle-in-cell simulations reproduced the experimental results, showing that the short-term magnetic turbulence via Weibel instability and the long-term quasi-static annular magnetic field by the streaming electric current account for the measured beam profile. Our work provides direct mapping of laser-driven proton sources in the space-energy domain and reveals the non-laminar beam evolution at featured time scales. [ABSTRACT FROM AUTHOR]

Published

2022

4. Enhanced Proton Acceleration from Laser Interaction with a Tailored Nanowire Target

Author

Yue Chao, Lihua Cao, Chunyang Zheng, Zhanjun Liu, and Xiantu He

Subjects

target normal sheath acceleration, nano-structured target, laser plasma interaction, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Target normal sheath field acceleration via laser interaction with structured solid targets has been widely studied for its potential use in a wide range of applications. Here, a novel nanowire target with a corrugated front surface is proposed to improve the proton acceleration by a target normal sheath field. Two-dimensional particle-in-cell simulations demonstrated that with the existence of the corrugated surface, the cut-off energy of accelerated protons nearly doubles compared to the planar nanowire target. When interacting with the corrugated surface, the incident laser pulse is reflected multiple times, focused and reinforced in each cavity near the front surface, which leads to suppression of the reflectivity and an improvement in the absorption rate. Electrons are heated more efficiently and the sheath field at the target rear side is naturally enhanced. To further investigate the performance of this novel target, a series of simulations with various laser intensities and target sizes were also carried out. This simple target design may provide insights for experiments in the future and should arouse interest because of its wide application.

Published

2022

5. Simultaneous observation of ultrafast electron and proton beams in TNSA.

Author

Bisesto, Fabrizio, Galletti, Mario, Anania, Maria Pia, Costa, Gemma, Ferrario, Massimo, Pompili, Riccardo, Zigler, Arie, Consoli, Fabrizio, Cipriani, Mattia, Salvadori, Martina, and Verona, Claudio

Subjects

*ELECTRON beams, *SOLID-state lasers, *NANODIAMONDS, *ULTRA-short pulsed lasers, *PROTON beams, *ION sources

Abstract

The interaction of ultra-intense high-power lasers with solid-state targets has been largely studied for the past 20 years as a future compact proton and ion source. Indeed, the huge potential established on the target surface by the escaping electrons provides accelerating gradients of TV/m. This process, called target normal sheath acceleration, involves a large number of phenomena and is very difficult to study because of the picosecond scale dynamics. At the SPARC_LAB Test Facility, the high-power laser FLAME is employed in experiments with solid targets, aiming to study possible correlations between ballistic fast electrons and accelerated protons. In detail, we have installed in the interaction chamber two different diagnostics, each one devoted to characterizing one beam. The first relies on electro-optic sampling, and it has been adopted to completely characterize the ultrafast electron components. On the other hand, a time-of-flight detector, based on chemical-vapour-deposited diamond, has allowed us to retrieve the proton energy spectrum. In this work, we report preliminary studies about simultaneous temporal resolved measurements of both the first forerunner escaping electrons and the accelerated protons for different laser parameters. [ABSTRACT FROM AUTHOR]

Published

2020

6. Light Ion Accelerating Line (L3IA): Test experiment at ILIL-PW.

Author

Gizzi, L.A., Baffigi, F., Brandi, F., Bussolino, G., Cristoforetti, G., Fazzi, A., Fulgentini, L., Giove, D., Koester, P., Labate, L., Maero, G., Palla, D., Romé, M., and Tomassini, P.

Subjects

*ION accelerators, *LINEAR accelerators, *PARTICLE accelerators, *PARTICLE physics, *COMPUTER simulation

Abstract

Abstract The construction of a novel Laser-driven Light Ions Acceleration Line (L3IA) is progressing rapidly towards the operation, following the recent upgrade of the ILIL-PW laser facility. The Line was designed on the basis of the pilot experimental activity carried out earlier at the same facility to define design parameters and to identify main components including target control and diagnostic equipment, also in combination with the numerical simulations for the optimization of laser and target parameters. A preliminary set of data was acquired following the successful commissioning of the laser system > 100 TW upgrade. Data include output from a range of different ion detectors and optical diagnostics installed for qualification of the laser–target interaction. An overview of the results is given along with a description of the relevant upgraded laser facility and features. [ABSTRACT FROM AUTHOR]

Published

2018

7. Summary of Working Group 2: Ion beams from plasmas.

Author

Borghesi, M. and Schramm, U.

Subjects

*ION beams, *PLASMA beam injection heating, *RADIATION pressure, *TARGETS (Nuclear physics), *PARTICLE acceleration, *LASER plasma accelerators

Published

2016

8. Investigations of ultrafast charge dynamics in laser-irradiated targets by a self probing technique employing laser driven protons.

Author

Ahmed, H., Kar, S., Cantono, G., Nersisyan, G., Brauckmann, S., Doria, D., Gwynne, D., Macchi, A., Naughton, K., Willi, O., Lewis, C.L.S., and Borghesi, M.

Subjects

*LASER beams, *TARGETS (Nuclear physics), *PROTON beams, *PROTON accelerators, *NUCLEAR physics experiments

Abstract

The divergent and broadband proton beams produced by the target normal sheath acceleration mechanism provide the unique opportunity to probe, in a point-projection imaging scheme, the dynamics of the transient electric and magnetic fields produced during laser-plasma interactions. Commonly such experimental setup entails two intense laser beams, where the interaction produced by one beam is probed with the protons produced by the second. We present here experimental studies of the ultra-fast charge dynamics along a wire connected to laser irradiated target carried out by employing a ‘self’ proton probing arrangement – i.e. by connecting the wire to the target generating the probe protons. The experimental data shows that an electromagnetic pulse carrying a significant amount of charge is launched along the wire, which travels as a unified pulse of 10s of ps duration with a velocity close to speed of light. The experimental capabilities and the analysis procedure of this specific type of proton probing technique are discussed. [ABSTRACT FROM AUTHOR]

Published

2016

9. Fabrication of nanostructured targets for improved laser-driven proton acceleration.

Author

Barberio, M., Scisciò, M., Veltri, S., and Antici, P.

Subjects

*PROTON accelerators, *FABRICATION (Manufacturing), *PARTICLE accelerators, *LITHOGRAPHY techniques, *LASER ablation

Abstract

In this work, we present a novel realization of nanostructured targets suitable for improving laser-driven proton acceleration experiments, in particular with regard to the Target-Normal-Sheath Acceleration (TNSA) acceleration mechanism. The nanostructured targets, produced as films, are realized by a simpler and cheaper method than using conventional lithographic techniques. The growth process includes a two step approach for the production of the gold nanoparticle layers: 1) Laser Ablation in Solution and 2) spray-dry technique using a colloidal solution on target surfaces (Aluminum, Mylar and Multi Walled Carbon Nanotube). The obtained nanostructured films appear, at morphological and chemical analysis, uniformly nanostructured and the nanostructure distributed on the target surfaces without presence of oxides or external contaminants. The obtained targets show a broad optical absorption in all the visible region and a surface roughness that is two times greater than non-nanostructured targets, enabling a greater laser energy absorption during the laser-matter interaction experiments producing the laser-driven proton acceleration. [ABSTRACT FROM AUTHOR]

Published

2016

10. Summary of working group 2: Ion beams from plasmas.

Author

Flacco, A. and Willingale, L.

Subjects

*ION beams, *LASER plasmas, *LASER beams, *NEUTRONS, *ANTINEUTRONS, *PROTONS

Abstract

Abstract We briefly summarize the contributions presented during the working group 2 (WG2) sessions. [ABSTRACT FROM AUTHOR]

Published

2018

11. MeV proton acceleration at kHz repetition rate from ultra-intense laser liquid interaction

Author

John T Morrison, Scott Feister, Kyle D Frische, Drake R Austin, Gregory K Ngirmang, Neil R Murphy, Chris Orban, Enam A Chowdhury, and W M Roquemore

Subjects

ion acceleration, MeV proton acceleration, laser–plasma interaction, ultra-intense laser solid interaction, target normal sheath acceleration, particle-in-cell, Science, Physics, QC1-999

Abstract

Laser acceleration of ions to ≳MeV energies has been achieved on a variety of Petawatt laser systems, raising the prospect of ion beam applications using compact ultra-intense laser technology. However, translation from proof-of-concept laser experiment into real-world application requires MeV-scale ion energies and an appreciable repetition rate (>Hz). We demonstrate, for the first time, proton acceleration up to 2 MeV energies at a kHz repetition rate using a milli-joule-class short-pulse laser system. In these experiments, 5 mJ of ultrashort-pulse laser energy is delivered at an intensity near $5\times {10}^{18}\,{\rm{W}}\,{\mathrm{cm}}^{-2}$ onto a thin-sheet, liquid-density target. Key to this effort is a flowing liquid ethylene glycol target formed in vacuum with thicknesses down to 400 nm and full recovery at 70 μ s, suggesting its potential use at ≫kHz rate. Novel detectors and experimental methods tailored to high-repetition-rate ion acceleration by lasers were essential to this study and are described. In addition, particle-in-cell simulations of the laser–plasma interaction show good agreement with experimental observations.

Published

2018

12. New scheme to produce aneutronic fusion reactions by laser-accelerated ions.

Author

Baccou, C., Depierreux, S., Yahia, V., Neuville, C., Goyon, C., De Angelis, R., Consoli, F., Ducret, J.E., Boutoux, G., Rafelski, J., and Labaune, C.

Abstract

The development of high-intensity lasers has opened the field of nuclear reactions initiated by laser-accelerated particles. One possible application is the production of aneutronic fusion reactions for clean fusion energy production. We propose an innovative scheme based on the use of two targets and present the first results obtained with the ELFIE facility (at the LULI Laboratory) for the proton–boron-11 (p–11B) fusion reaction. A proton beam, accelerated by the Target Normal Sheat Acceleration mechanism using a short laser pulse (12 J, 350 fs, 1.056 µm, 1019 W cm−2), is sent onto a boron target to initiate fusion reactions. The number of reactions is measured with particle diagnostics such as CR39 track-detectors, active nuclear diagnostic, Thomson Parabola, magnetic spectrometer, and time-of-flight detectors that collect the fusion products: the α-particles. Our experiment shows promising results for this scheme. In the present paper, we discuss its principle and advantages compared with another scheme that uses a single target and heating mechanisms directly with photons to initiate the same p–11B fusion reaction. [ABSTRACT FROM PUBLISHER]

Published

2015

13. Preparation of laser-accelerated proton beams for radiobiological applications

Author

Metzkes, J., Cowan, T.E., Karsch, L., Kraft, S.D., Pawelke, J., Richter, C., Richter, T., Zeil, K., and Schramm, U.

Subjects

*PROTON beams, *PARTICLE acceleration, *LASER beams, *RADIOBIOLOGY, *ION accelerators, *MAGNETIC dipoles, *PROTON spectra, *BACKGROUND radiation

Abstract

Abstract: This paper presents the concept of transport and filtering of laser-accelerated proton pulses used for the first cell irradiation experiments performed with the Dresden 150TW laser DRACO. Based on a simple non-focusing magnetic dipole equipped with two apertures the concept makes use of an energy dependent angular asymmetry of the proton spectra. For micron thin target foils protons of interest with energies above 7MeV are observed to be significantly offset from target normal where low energy emission is dominantly centered. As the effect can be controlled via the target rotation with respect to the incoming light, it can be used to optimize the transport efficiency for high energy protons while simultaneously suppressing background radiation. [Copyright &y& Elsevier]

Published

2011

14. Comparison of femtosecond laser-driven proton acceleration using nanometer and micrometer thick target foils.

Author

Schnürer, M., Andreev, A.A., Steinke, S., Sokollik, T., Paasch-Colberg, T., Nickles, P.V., Henig, A., Jung, D., Kiefer, D., Hörlein, R., Schreiber, J., Tajima, T., Habs, D., and Sandner, W.

Subjects

PROTON accelerators, LASER-induced breakdown spectroscopy, METAL foils, ULTRASHORT laser pulses, ELECTRON distribution, ION energy, IRRADIATION

Abstract

Advancement of ion acceleration by intense laser pulses is studied with ultra-thin nanometer-thick diamond like carbon and micrometer-thick Titanium target foils. Both investigations aim at optimizing the electron density distribution which is the key for efficient laser driven ion acceleration. While recently found maximum ion energies achieved with ultra-thin foils mark record values micrometer thick foils are flexible in terms of atomic constituents. Electron recirculation is one prerequisite for the validity of a very simple model that can approximate the dependence of ion energies of nanometer-thick targets when all electrons of the irradiated target area interact coherently with the laser pulse and Coherent Acceleration of Ions by Laser pulses (CAIL) becomes dominant. Complementary experiments, an analytical model and particle in cell computer simulations show, that with regard to ultra-short laser pulses (duration ~45 fs at intensities up to 5 × 1019 W/cm2) and a micrometer-thick target foil with higher atomic number a close to linear increase of ion energies manifests in a certain range of laser intensities. [ABSTRACT FROM PUBLISHER]

Published

2011