Your search keyword '"Target normal sheath acceleration"' showing total 41 results

1. Multispecies ion acceleration from intense laser interactions with thin foils

Author

McIlvenny, Aodhan, Borghesi, Marco, and Kar, Satyabrata

Subjects

539.7, laser ion acceleration, ion acceleration, light sail, hole boring, target normal sheath acceleration, relativistic transparency, multispecies, radiation pressure acceleration, polarisation, carbon, protons

Abstract

The understanding and demonstration of novel laser driven ion acceleration mechanisms is key to overcoming the limitations of both well understood laser based processes and becoming competitive with conventional particle accelerators. This thesis presents two methods of enhancing the ion energies achievable in thin solid targets irradiated by intense laser pulses. In the first approach, the transition to the Light-Sail Radiation Pressure Acceleration mechanism was explored with the use of ultra-thin foils, and a contrast enhanced circular polarised pulse with a peak intensity of 5.5×10 Wcm⁻². The experimental data indicates the presence of an (intensity dependent) optimum thickness of 15 nm for C⁶⁺ (33 MeV/nucleon) where a local minimum of 18 MeV is instead observed for H⁺. At this thickness, each species’ maximum energy is shown to scale differently with laser intensity; C⁶⁺ scales favourably in the radiation pressure scheme (I¹.²) with protons scaling much slower, indicating acceleration by plasma heating. This species dependence is attributed to the precursor laser intensity impinging onto the target. This is shown to result in a multi-species expansion which allows for the preferential acceleration of bulk C⁶⁺ ions over sheath accelerated H⁺ which are displaced from the target prior to the arrival of the main intensity peak. This is shown for the first time and is of major significance to the development of laser based ion accelerators at currently available, and future, high power lasers. The second approach indicates the enhancement of radiation pressure accelerated ions in temporally stretched pulses, with a lower peak intensity, by measuring both higher ion energies and a greater red-shift in the back reflected light than for a fully compressed, higher intensity pulse. This is against what would be expected in a typical interaction. It is shown that proton energies are increased from 30 MeV to 50 MeV by stretching the pulse by over a factor of 2 with the maximum red-shift of the 2nd harmonic increasing from 55 nm to 75 nm, indicating an enhanced hole boring velocity from 0.1c to 0.14c. Numerical simulations indicate that this effect is due to the development of a hot electron current, and subsequently equalising return currents, in the overdense bulk plasma, which result in the growth of significant (10’s kT) magnetic fields within the target. These currents repel and cause a significant drop in target density reducing the internal plasma pressure and allowing radiation pressure to dominate on the front surface over what is observed with the higher intensity pulses. The experimental trends are qualitatively reproduced and the enhancement of front surface acceleration is demonstrated.

Published

2021

2. 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

3. 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

4. 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

5. 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

6. 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

7. Ion Acceleration I: Efficient Heavy Ion Acceleration by ESA

Author

Ji, Liangliang and Ji, Liangliang

Published

2014

8. Ion Acceleration in Subcritical Density Plasma via Interaction of Intense Laser Pulse with Cluster-Gas Target

Author

Fukuda, Y., Faenov, A. Ya., Tampo, M., Pikuz, T. A., Nakamura, T., Kando, M., Hayashi, Y., Yogo, A., Sakaki, H., Kameshima, T., Kawase, K., Pirozhkov, A. S., Ogura, K., Mori, M., Esirkepov, T. Zh., Koga, J., Boldarev, A. S., Gasilov, V. A., Magunov, A. I., Yamauchi, T., Kodama, R., Bolton, P. R., Kondo, K., Kawanishi, S., Kato, Y., Tajima, T., Daido, H., Bulanov, S. V., Yamanouchi, Kaoru, editor, Charalambidis, Dimitrios, editor, and Normand, Didier, editor

Published

2011

9. Enhancement of proton acceleration from focusing targets

Author

Smith, Herbie Lamar and 0000-0002-2310-1424

Subjects

Target normal sheath acceleration, Proton acceleration, TNSA, High energy density physics, Laser-plasma interactions

Abstract

Particle acceleration from laser-plasma interactions has been a vibrant area of research since the discovery of electron and proton beams emitted from high intensity laser-plasma interactions in the 1980s. Since then, a large body of work has developed in pursuit of understanding and controlling the mechanisms that generate these particle beams, as well as the beams themselves. In particular, proton beams have a rich set of applications in the fields of medicine, fusion energy, and fundamental physics that motivates their study. In this thesis, we first discuss the laser technology that has enabled this research. We follow this with detailed information on the design and development of a 100 TW power upgrade to the graduate student-run GHOST laser system for the purposes of conducting repetition-rated laser-plasma experiments. We then outline the physics that drives particle acceleration during the interactions of high intensity lasers and solid targets with a particular focus on target normal sheath acceleration, the most widely studied laser-plasma particle acceleration mechanism. Finally, we describe experiments conducted on the Texas Petawatt Laser system to test an approach to enhance the yield, peak energy, and beam characteristics of proton beams generated by laser-plasma interactions with the use of focusing targets.

Published

2022

10. 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

11. Applications of Laser-Plasma Acceleration

Author

Svendsen, Kristoffer and Svendsen, Kristoffer

Abstract

This thesis is dedicated to the investigation of laser-plasma particle acceleration concepts. Some of the work was focused on improving electron and proton acceleration for future applications, in terms of maximizing the particle energy and minimizing the divergence of the X-ray beams. In laser wakefield acceleration, a very intense laser pulse (> 1018 W/cm2) is focused in a gas. The leading edge of the pulse is intense enough to ionize the gas, and the main part of the pulse interacts with a plasma. Under the action of the ponderomotive force, the intense laser pulse can expel plasma electrons and form a wake in the plasma that trails the laser pulse. This charge separation leads to the formation of an ion cavity that results in electromagnetic fields several orders of magnitude stronger than those in conventional accelerators, up to TV/m. Some electrons can be accelerated to several hundred MeV over distances of less than a cm by injecting them into the plasma wake. There are also focusing forces inside the plasma wake, and the injected electrons will oscillate transversely about the optical axis, producing multi-keV betatron X-ray radiation. This radiation is directed along the optical axis with a low divergence of a few tens of mrad. One application investigated in this work was the possibility of using laser-wakefield-accelerated electrons for very high-energy electron (VHEE) radiotherapy. High-energy electrons can reach deep tumours with limited scattering, and have a more suitable dose-depth profile than photon beams. In this work, a VHEE beam was focused inside a phantom using electromagnetic quadrupoles to mimic stereotactic radiotherapy. The X-ray beam generated by LWFA was used to measure the equivalent path length and 3D liquid mass distribution in commercial fuel injectors by tomographic reconstruction. It was shown that the sensitivity (in terms of the detectable liquid mass) was comparable to that possible with large synchrotron facilities. Furthermor

Published

2022

12. 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

13. 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

14. 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

15. 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

16. Surrogate Modeling of Ion Acceleration with Invertible Neural Networks

Author

Miethlinger, T., (0000-0001-6994-2475) Garten, M., Göthel, I., Hoffmann, N., (0000-0003-0390-7671) Schramm, U., (0000-0003-4861-5584) Kluge, T., Miethlinger, T., (0000-0001-6994-2475) Garten, M., Göthel, I., Hoffmann, N., (0000-0003-0390-7671) Schramm, U., and (0000-0003-4861-5584) Kluge, T.

Abstract

The interaction of overdense plasma with ultra-intense laser pulses presents a promising approach to enable the development of very compact ion sources. Prospective applications of high-energetic protons and ions include, but are not limited to, medical applications (in particular ion beam radiotherapy), laboratory astrophysics and nuclear fusion. However, current records for maximum proton energies (94 MeV, 2018) are still below the required values for the aforementioned applications (typically in the range of 150-250 MeV), and especially challenges such as stability and spectral control remain unsolved to this day. In particular, significant effort per experiment and a high-dimensional design space renders naive sampling approaches ineffective. Furthermore, due to the strong nonlinearities of the underlying laser-plasma physics, synthetic observations by means of particle-in-cell (PIC) simulations are computationally very costly, and the maximum distance between two sampling points is strongly limited as well. Consequently, in order to build useful surrogate models for future data generation and experimental understanding and control, a combination of highly optimized simulation codes (where we employ PIConGPU), powerful data-based methods, such as artificial neural networks (ANNs), and modern sampling approaches are essential. Specifically, we employ invertible neural networks for bidirectional learning of input (parameter) and output (observables) and convolutional autoencoder to reduce intermediate field data to a lower-dimensional latent representation.

Published

2021

17. Target and Laser Pulse Optimization for Laser-Driven Ion Acceleration

Author

Permogorov, Alexander and Permogorov, Alexander

Abstract

The research presented in this thesis is primarily focused on experimental investigations of laser-driven ion acceleration from solid targets via the target normal sheath acceleration mechanism. In particular, ways of optimizing the absorption of the laser pulse energy by free plasma electrons in the target, or modifying the shape of the accelerating electron sheath were addressed. The aim of this work was to increase the efficiency, and maximum proton energy that could be obtained with a given laser system, and to reduce the divergence of the beams of accelerated protons.The shape of the electrostatic sheath was indirectly influenced by using laser micromachining to modify the front surface of the target, on which the laser pulse is incident. The absorption of the laser pulse was enhanced by either placing nanostructures on the front side of the foil target, or by manipulating the temporal profile of the ultrafast part of the laser pulse before its interaction with an ultrathin target.It is important to ensure the survival of the target by using a laser pulse with very high temporal contrast. A double plasma mirror (DPM) was designed and implemented for this purpose. Design considerations and the optimization of the performance of the DPM, which is now used routinely at the Lund High-Power Laser Facility during laser-solid interaction studies, are discussed. Sufficiently high temporal contrast was achieved, and an increase was seen in the maximum proton kinetic energy when using targets with nanowire and foam structures on the surface. Efficient ion acceleration from ultrathin targets with a thickness down to 10 nm was observed as well.When an ultrafast laser pulse interacts with an ultrathin foil, the temporal shape of the electric field of the pulse affects the laser--solid interaction, and a slightly positively chirped pulse was found to increase the maximum kinetic energy of the accelerated protons.Laser-solid interactions at very high intensities are known to

Published

2021

18. Laser Driven Ion Acceleration Study in JAEA.

Author

Kondo, K.

Subjects

*ION accelerators, *MICROMETERS, *PROTON accelerators, *LASER pulses, *ENERGY intensity (Economics)

Published

2014

19. 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

20. 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

21. PIC Simulations Of Ion Acceleration By Linearly And Circularly Polarized Laser Pulses.

Author

Limpouch, Jiri, Klimo, Ondrej, Psikal, Jan, Tikhonchuk, Vladimir T., Kawata, Shigeo, and Andreev, Alexander A.

Subjects

*PARTICLES (Nuclear physics), *LASER beams, *ACCELERATION (Mechanics), *PROTONS, *OSCILLATING chemical reactions, *IONS, *PONDEROMOTIVE force

Abstract

Linearly polarized laser radiation accelerates electrons to very high velocities and these electron form a sheath layer on the rear side of thin targets where preferentially protons are accelerated. When mass-limited targets are used, the lateral transport of the absorbed laser energy is reduced and the accelerating field is enhanced. For targets consisting of two ion species, heavier ions facilitate formation of quasi-monoenergetic bunch of lighter ions. For circularly polarized light, fast electron production is suppressed by the absence of the oscillatory component of the ponderomotive force. Ions are accelerated on the front side by the separation field and very thin foil can be accelerated as one massive quasi-neutral block. As all ion species acquire the same velocity, this acceleration mechanism is preferred for heavier ions. [ABSTRACT FROM AUTHOR]

Published

2008

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

Author

Claudio Verona, M. Salvadori, Maria Pia Anania, Fabrizio Bisesto, Mario Galletti, Fabrizio Consoli, G. Costa, Arie Zigler, M. Cipriani, Riccardo Pompili, Massimo Ferrario, Bisesto, F., Galletti, M., Anania, M. P., Costa, G., Ferrario, M., Pompili, R., Zigler, A., Consoli, F., Cipriani, M., Salvadori, M., and Verona, C.

Subjects

Nuclear and High Energy Physics, Proton, time-of-flight diagnostics, Electron, 01 natural sciences, 010305 fluids & plasmas, law.invention, laser-plasma interaction, law, 0103 physical sciences, high-power laser, TNSA, EOS crystal, TOF measurements, 010306 general physics, Settore FIS/01, Physics, electro-optic sampling diagnostics, Detector, Laser, Atomic and Molecular Physics, and Optics, Ion source, Electronic, Optical and Magnetic Materials, Computational physics, Nuclear Energy and Engineering, Picosecond, Physics::Accelerator Physics, ultrashort high-intensity laser pulses, Ultrashort pulse, Beam (structure), target normal sheath acceleration

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.

Published

2020

23. 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

24. 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

25. Ion Acceleration by High Intensity Pulsed Laser: Transport, Diagnostics and Theoretical Modelling

Author

Costa, Giuseppe

Subjects

plasma diagnostics, time-of-flight technique, Settore FIS/01 - Fisica Sperimentale, Thomson Parabola Spectrometer, longitudinal electric field, ion acceleration, computational analysis, Laser-produced Plasma, advanced target, electron density, Backward Plasma Acceleration, Target Normal Sheath Acceleration, particle-in-cell simulations

Published

2019

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

Author

D. Gwynne, Andrea Macchi, K. Naughton, Gagik Nersisyan, Satyabrata Kar, Domenico Doria, Marco Borghesi, Oswald Willi, Ciaran Lewis, Hamad Ahmed, G. Cantono, and S. Brauckmann

Subjects

Physics, Nuclear and High Energy Physics, Proton, Target charging, Laser, 01 natural sciences, Proton probing, 010305 fluids & plasmas, Magnetic field, law.invention, Pulse (physics), Acceleration, law, 0103 physical sciences, Target normal sheath acceleration, Physics::Accelerator Physics, Atomic physics, 010306 general physics, Instrumentation, Ultrashort pulse, Beam (structure), Electromagnetic pulse

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. (C) 2016 Elsevier B.V. All rights reserved.

Published

2016

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

Author

Patrizio Antici, Marianna Barberio, M. Scisciò, and S. Veltri

Subjects

Materials science, Nanostructure, Nanoparticle, Nanotechnology, Carbon nanotube, 01 natural sciences, 010305 fluids & plasmas, law.invention, Acceleration, law, 0103 physical sciences, Target normal sheath acceleration, Surface roughness, Gold nanoparticles, General Materials Science, Electrical and Electronic Engineering, 010306 general physics, Absorption (electromagnetic radiation), Laser plasma targetry, Nanostructured target, Laser ablation, Laser-driven proton acceleration, Condensed Matter Physics, Laser, Laser-matter interaction, Materials Science (all)

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.

Published

2016

28. Ring-like spatial distribution of laser accelerated protons in the ultra-high-contrast TNSA-regime

Author

Becker, G. A., Tietze, S., Keppler, S., Reislöhner, J., Bin, J. H., Bock, L., Brack, F.-E., Hein, J., Hellwing, M., Hilz, P., Hornung, M., Kessler, A., Kraft, S. D., Kuschel, S., Liebetrau, H., Ma, W., Polz, J., Schlenvoigt, H.-P., Schorcht, F., Schwab, M. B., Seidel, A., Zeil, K., Schramm, U., Zepf, M., Schreiber, J., Rykovanov, S., Kaluza, M. C., Becker, G. A., Tietze, S., Keppler, S., Reislöhner, J., Bin, J. H., Bock, L., Brack, F.-E., Hein, J., Hellwing, M., Hilz, P., Hornung, M., Kessler, A., Kraft, S. D., Kuschel, S., Liebetrau, H., Ma, W., Polz, J., Schlenvoigt, H.-P., Schorcht, F., Schwab, M. B., Seidel, A., Zeil, K., Schramm, U., Zepf, M., Schreiber, J., Rykovanov, S., and Kaluza, M. C.

Abstract

The spatial distribution of protons accelerated from submicron-thick plastic foil targets using multi-terawatt, frequency-doubled laser pulses with ultra-high temporal contrast has been investigated experimentally. A very stable, ring-like beam profile of the accelerated protons, oriented around the target's normal direction has been observed. The ring's opening angle has been found to decrease with increasing foil thicknesses. Two-dimensional particle-in-cell simulations reproduce our results indicating that the ring is formed during the expansion of the proton density distribution into the vacuum as described by the mechanism of target-normal sheath acceleration. Here - in addition to the longitudinal electric fields responsible for the forward acceleration of the protons - a lateral charge separation leads to transverse field components accelerating the protons in the lateral direction.

Published

2018

29. Study of laser-plasma interaction with particle-in-cell simulations: attosecond pulse generation and proton acceleration

Author

Flores Arias, María Teresa, Universidade de Santiago de Compostela. Centro Internacional de Estudos de Doutoramento e Avanzados (CIEDUS), Universidade de Santiago de Compostela. Escola de Doutoramento Internacional en Ciencias e Tecnoloxía, Universidade de Santiago de Compostela. Programa de Doutoramento en Láser, Fotónica e Visión, Blanco Fraga, Manuel, Flores Arias, María Teresa, Universidade de Santiago de Compostela. Centro Internacional de Estudos de Doutoramento e Avanzados (CIEDUS), Universidade de Santiago de Compostela. Escola de Doutoramento Internacional en Ciencias e Tecnoloxía, Universidade de Santiago de Compostela. Programa de Doutoramento en Láser, Fotónica e Visión, and Blanco Fraga, Manuel

Abstract

The advancement of lasers over the last decades has allowed researchers to explore new regimes of physics and their applications. High power lasers interacting with plasmas have provided with the tools to create high frequency ultrashort pulsed radiation, near the X-ray regime and with temporal lengths on the attosecond scale, and has allowed to create compact and cheap particle accelerators. Numerical simulations are a fundamental tool in the advancement of this scientific area, since they provide with insights into the physical processes involved and they can be used to design experiments. In this thesis we present the results of numerical simulations for ultrashort pulse production, ion acceleration and other laser-plasma applications.

Published

2018

30. Light Ion Accelerating Line (L3IA): Test Experiment at ILIL-PW

Author

Lorenzo Fulgentini, Petra Koester, L. Labate, Fernando Brandi, L. A. Gizzi, F. Baffigi, G. C. Bussolino, D. Palla, Massimiliano Romé, Gabriele Cristoforetti, Paolo Tomassini, Giancarlo Maero, Alberto Fazzi, and Dario Giove

Subjects

Nuclear and High Energy Physics, Nuclear engineering, FOS: Physical sciences, 01 natural sciences, 010305 fluids & plasmas, Ion, law.invention, Acceleration, law, 0103 physical sciences, Target normal sheath acceleration, Ion detection, 010306 general physics, Instrumentation, Gas chromatography ion detector, Physics, Laser–plasma acceleration, Ultraintense lasers, Laser, Physics - Plasma Physics, Line (electrical engineering), Plasma Physics (physics.plasm-ph), Upgrade, Optical diagnostics, Target control, Laser-plasma acceleration

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 following 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., 6 pages, 7 figures, 18 references, presented at the EAAC 2017

Published

2018

31. Study of laser-plasma interaction with particle-in-cell simulations: attosecond pulse generation and proton acceleration

Author

Blanco Fraga, Manuel, Flores Arias, María Teresa, Universidade de Santiago de Compostela. Centro Internacional de Estudos de Doutoramento e Avanzados (CIEDUS), Universidade de Santiago de Compostela. Escola de Doutoramento Internacional en Ciencias e Tecnoloxía, and Universidade de Santiago de Compostela. Programa de Doutoramento en Láser, Fotónica e Visión

Subjects

High harmonic generation, Laser-plasma interaction, Physics::Plasma Physics, Investigación::22 Física::2204 Física de fluidos::220410 Física de plasmas [Materias], Investigación::22 Física::2202 Electromagnetismo::220207 Interacción de ondas electromagnéticas con la materia [Materias], Physics::Optics, Particle-in-cell simulations, Physics::Atomic Physics, Target Normal Sheath Acceleration

Abstract

The advancement of lasers over the last decades has allowed researchers to explore new regimes of physics and their applications. High power lasers interacting with plasmas have provided with the tools to create high frequency ultrashort pulsed radiation, near the X-ray regime and with temporal lengths on the attosecond scale, and has allowed to create compact and cheap particle accelerators. Numerical simulations are a fundamental tool in the advancement of this scientific area, since they provide with insights into the physical processes involved and they can be used to design experiments. In this thesis we present the results of numerical simulations for ultrashort pulse production, ion acceleration and other laser-plasma applications.

Published

2018

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

Author

Louise Willingale, Alessandro Flacco, Laboratoire d'optique appliquée (LOA), and École Nationale Supérieure de Techniques Avancées (ENSTA Paris)-École polytechnique (X)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, Radiation pressure acceleration, Nuclear and High Energy Physics, [PHYS.PHYS.PHYS-ACC-PH]Physics [physics]/Physics [physics]/Accelerator Physics [physics.acc-ph], Plasma, 01 natural sciences, Laser driven neutron generation, Laser plasma ion acceleration, 010305 fluids & plasmas, Ion, Nuclear physics, Group (periodic table), 0103 physical sciences, Target normal sheath acceleration, 010306 general physics, Instrumentation, Laser-accelerated particles applications

Abstract

International audience; We briefly summarize the contributions presented during the working group 2 (WG2) sessions.

Published

2017

33. Laser-driven proton acceleration with nanostructured targets

Author

Antonia Morabito, M. Scisciò, S. Veltri, S. Vallières, Patrizio Antici, and Marianna Barberio

Subjects

Photon, Materials science, Proton, Physics::Optics, Nanoparticle, Buckypaper, Nanotechnology, 02 engineering and technology, 01 natural sciences, nanostructured targets, law.invention, Acceleration, law, 0103 physical sciences, Electronic, Optical and Magnetic Materials, Electrical and Electronic Engineering, 010306 general physics, Absorption (electromagnetic radiation), laser-driven particle acceleration, laser-matter interaction, plasma physics, business.industry, Applied Mathematics, Computer Science Applications1707 Computer Vision and Pattern Recognition, Condensed Matter Physics, 021001 nanoscience & nanotechnology, Laser, Particle acceleration, nanoparticles, target normal sheath acceleration, Electronic, Optical and Magnetic Materials, Physics::Accelerator Physics, Optoelectronics, 0210 nano-technology, business

Abstract

Laser-driven particle acceleration has become a growing field of research, in particular for its numerous interesting applications. One of the most common proton acceleration mechanism that is obtained on typically available multi-hundred TW laser systems is based on the irradiation of thin solid metal foils by the intense laser, generating the proton acceleration on its rear target surface. The efficiency of this acceleration scheme strongly depends on the type of target used. Improving the acceleration mechanism, i.e. enhancing parameters such as maximum proton energy, laminarity, efficiency, monocromaticy, and number of accelerated particles, is heavily depending on the laser-to-target absorption, where obviously cheap and easy to implement targets are best candidates. In this work, we present nanostructured targets that are able to increase the absorption of light compared to what can be achieved with a classical solid (non-nanostructured) target and are produced with a method that is much simpler and cheaper than conventional lithographic processes. Several layers of gold nanoparticles were deposited on solid targets (aluminum, Mylar and multiwalled carbon nanotube buckypaper) and allow for an increased photon absorption. This ultimately permits to increase the laser-to-particle energy transfer, and thus to enhance the yield in proton production. Experimental characterization results on the nanostructured films are presented (UV-Vis spectroscopy and AFM), along with preliminary experimental proton spectra obtained at the JLF-TITAN laser facility at LLNL.

Published

2017

34. Efficient laser production of energetic neutral beams

Author

Dimitri Batani, G. Birindelli, F Mollica, J. Braenzel, M. Schnuerer, B. Vauzour, Giulia Folpini, Alessandro Flacco, Victor Malka, Luca Antonelli, Sources compactes de Particules pour Lasers & Applications (SPL), Laboratoire d'optique appliquée (LOA), École Nationale Supérieure de Techniques Avancées (ENSTA Paris)-École polytechnique (X)-Centre National de la Recherche Scientifique (CNRS)-École Nationale Supérieure de Techniques Avancées (ENSTA Paris)-École polytechnique (X)-Centre National de la Recherche Scientifique (CNRS), Università di Roma Tor Vergata, Università di Roma La Sapienza, Technische Universität Berlin (TU), Max-Born-institut, Max-Born-institut, Berlin, Centre d'Etudes Lasers Intenses et Applications (CELIA), Centre National de la Recherche Scientifique (CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université de Bordeaux (UB), European Project: 284464,EC:FP7:INFRA,FP7-INFRASTRUCTURES-2011-1,LASERLAB-EUROPE(2012), Technical University of Berlin / Technische Universität Berlin (TU), and Université de Bordeaux (UB)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Materials science, neutral beam, Hydrogen, chemistry.chemical_element, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Ion, law.invention, laser-plasma interaction, law, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], 0103 physical sciences, Atom, 010306 general physics, ions laser-acceleration, [PHYS.PHYS.PHYS-OPTICS]Physics [physics]/Physics [physics]/Optics [physics.optics], Argon, Energetic neutral atom, charge transfer, Laser, Condensed Matter Physics, chemistry, Nuclear Energy and Engineering, Atomic physics, Nucleon, target normal sheath acceleration, Beam (structure)

Abstract

International audience; Laser-driven ion acceleration by intense, ultra-short, laser pulse has received increasing attention inrecent years, and the availability of much compact and versatile ions sources motivates the study oflaser-driven sources of energetic neutral atoms. We demonstrate the production of a neutral anddirectional beam of hydrogen and carbon atoms up to 200 keV per nucleon, with a peak flow of 2.7 x10(13) atom s(-1). Laser accelerated ions are neutralized in a pulsed, supersonic argon jet with tunabledensity between 1.5 x 10(17) cm(-3) and 6 x 10(18) cm(-3). The neutralization efficiency has beenmeasured by a time-of-flight detector for different argon densities. An optimum is found, for whichcomplete neutralization occurs. The neutralization rate can be explained only at high areal densities (> 1x 10(17) cm(-2)) by single electron charge transfer processes. These results suggest a new perspectivefor the study of neutral production by laser and open discussion of neutralization at a lower density.

Published

2016

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

Author

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

Subjects

Nuclear reaction, Fusion, Photon, Materials science, Spectrometer, Aneutronic fusion, Particle diagnostics, Fusion power, Laser-accelerated ions, Aneutronic reactions, Proton-boron fusion reaction, Target normal sheath acceleration, Condensed Matter Physics, Laser, Atomic and Molecular Physics, and Optics, Laser-accelerated ion, Aneutronic reaction, Particle diagnostic, law.invention, Nuclear physics, law, Nuclear fusion, Electrical and Electronic Engineering

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.

Published

2015

36. Charged-particle acceleration through laser irradiation of thin foils at Prague Asterix Laser System

Author

Lorenzo Torrisi, E. Krousky, Miroslav Pfeifer, A. Zaras-Szydlowska, Paolo Musumeci, Andreiy Velyhan, Lucia Calcagno, Jiri Skala, Marcin Rosinski, Jiri Ullschmied, M. Cutroneo, S. Cavallaro, and Jerzy Wolowski

Subjects

Materials science, Spectrometer, plasma diagnostics, business.industry, Streak camera, Electron, Laser, Condensed Matter Physics, ion acceleration, Atomic and Molecular Physics, and Optics, Particle detector, Charged particle, Ion, law.invention, target normal sheath acceleration, Mathematical Physics, Optics, law, Atomic and Molecular Physics, Irradiation, Atomic physics, and Optics, business

Abstract

Thin foils, 0.5–50 μm in thickness, have been irradiated in vacuum at Prague Asterix Laser System in Prague using 1015–16 W cm−2 laser intensity, 1315 nm wavelength, 300 ps pulse duration and different focal positions. Produced plasmas from metals and polymers films have been monitored in the forward and backward directions. Ion and electron accelerations have been investigated by using Thomson parabola spectrometer, x-ray streak camera, ion collectors and SiC semiconductor detectors, the latter employed in time-of-flight configuration. Ion acceleration up to about 3 MeV per charge state was measured in the forward direction. Ion and electron emissions were detected at different angles as a function of the irradiation conditions.

Published

2014

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

Author

T. Richter, Christian Richter, J. Metzkes, Jörg Pawelke, Stephan Kraft, Ulrich Schramm, Thomas E. Cowan, Karl Zeil, and Leonhard Karsch

Subjects

Physics, Nuclear and High Energy Physics, High energy, Offset (computer science), Proton, business.industry, magnetic energy filter, media_common.quotation_subject, Laser, Asymmetry, law.invention, Optics, laser acceleration of ions, law, Physics::Accelerator Physics, radiobiological studies, Irradiation, Atomic physics, business, Instrumentation, Magnetic dipole, target normal sheath acceleration, Background radiation, media_common

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 150 TW 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 7 MeV 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.

Published

2011

38. Studies of Ion Acceleration from Thin Solid-Density Targets on High-Intensity Lasers

Author

Willis, Christopher Ryan

Subjects

Physics, High-intensity, lasers, ion acceleration, High energy density physics, target normal sheath acceleration, protons, ions

Abstract

Over the past two decades, a number of experiments have been performed demonstrating the acceleration of ions from the interaction of an intense laser pulse with a thin, solid density target. These ions are accelerated by quasi-static electric fields generated by energetic electrons produced at the front of the target, resulting in ion energies up to tens of MeV. These ions have been widely studied for a variety of potential applications ranging from treatment of cancer to the production of neutrons for advanced radiography techniques. However, realization of these applications will require further optimization of the maximum energy, spectrum, or species of the accelerated ions, which has been a primary focus of research to date. This thesis presents two experiments designed to optimize several characteristics of the accelerated ion beam. The first of these experiments took place on the GHOST laser system at the University of Texas at Austin, and was designed to demonstrate reliable acceleration of deuterium ions, as needed for the most efficient methods of neutron generation from accelerated ions. This experiment leveraged cryogenically cooled targets coated in D2O ice to suppress the protons which typically dominate the accelerated ions, producing as many as 2 x 10^10 deuterium ions per 1 J laser shot, exceeding the proton yield by an average ratio of 5:1.The second major experiment in this work was performed on the Scarlet laser system at The Ohio State University, and studied the accelerated ion energy, yield, and spatial distribution as a function of the target thickness. In principle, the peak energy increases with decreasing target thickness, with the thinnest targets accessing additional acceleration mechanisms which provide favorable scaling with the laser intensity. However, laser prepulse characteristics provide a lower bound for the target thickness, yielding an optimum target thickness for ion acceleration which is dependent on the laser system. This experiment utilized new liquid crystal film targets developed at OSU, which may be formed at variable thicknesses from tens of nanometers to several microns. On this experiment, an optimum ion energy and flux was reached for targets of 600-900 nm, providing a peak proton energy of 24 MeV, and total ion flux of >10^9 protons over 3.4 MeV from 5.5 J of laser energy at an intensity of 1 x 10^20 W/cm^2.The primary ion diagnostics for these two experiments are described in detail, including the analysis techniques needed to extract absolutely calibrated spatial and spectral distributions of the accelerated ions. Additionally, a new technique for target alignment is presented, providing repeatable target alignment on the micron scale. This allows for a repeatable laser intensity on target, allowing improved shot to shot consistency on high intensity experiments.In addition to these two experiments, work on the upgrade and characterization of the 400 TW Scarlet laser is discussed, including several calculations critical to the design and upgrade of the laser system, as well as prepulse characterization needed for experiments on thin targets.

Published

2016

39. Modeling Ion Acceleration Using LSP

Author

McMahon, Matthew M.

Subjects

Physics, Ion Acceleration, Target Normal Sheath Acceleration, Particle In Cell, Plasma Physics

Abstract

This thesis presents the development of simulations modeling ion acceleration using the particle-in-cell code LSP. A new technique was developed to model the Target Normal Sheath Acceleration (TNSA) mechanism. Multiplesimulations are performed, each optimized for a certain part of the TNSA process with appropriate informationbeing passed from one to the next. The technique allows for tradeoffs between accuracy and speed. Physical length and timescalesare met when necessary and different physical models are employed as needed.This TNSA modeling technique is used to perform a study on the effect front-surface structures have on the resultingion acceleration. The front-surface structures tested have been shown to either modify the electron kinetic energy spectrumby increasing the maximum energy obtained or by increasing the overall coupling of laser energy to electron energy. Both of these types of front-surface structures are tested for their potential benefits for the accelerated ions. It is shownthat optimizing the coupling of laser energy to electron energy is more important than producing extremely energetic electrons in the case of the TNSA ions.Simulations modeling the interaction of an intense laser with very thin (

Published

2015

40. The effect of laser contrast and target thickness on laser-plasma interactions at the Texas Petawatt

Author

Meadows, Alexander Ross

Subjects

Laser, Physics, Laser-plasma, Laser-plasma interactions, Target normal sheath acceleration, Break-out afterburner, Laser ion acceleration, Texas Petawatt, Petawatt, TPW

Abstract

A two-year experimental campaign is described during which diamond-like carbon and plastic targets with thicknesses from 20 nanometers to 15 micrometers were irradiated by the Texas Petawatt Laser. Target composition and thickness were varied to modify the specifics of the laser-matter interaction. Plasma mirrors were selectively implemented to affect the contrast of the laser system and provide additional control of the physical processes under investigation. A number of particle diagnostics were implemented to measure the distribution of laser accelerated ions and electrons. In addition, optical diagnostics were fielded to measure the intensity profile of the laser and measure the density of the target pre-plasma. The results of these experiments suggest that the Texas Petawatt laser pulse has pre-pulse and pedestal features with intensities at least 10⁻⁸ of the main pulse. Micronscale targets were able to survive these features and maintain a relatively sharp density gradient until the arrival of the main laser pulse, allowing for ion acceleration. Electron spectra measured in this configuration show an average temperature of 10 MeV, with no v angular dependence out to at least 60 degrees. By contrast, interferometric plasma density measurements and a lack of any observable ion acceleration suggest that nanoscale targets were destroyed well before the main pulse. In this case, the peak of the laser pulse interacted with a cloud of plasma between 10⁻³ and 10⁻² of critical density. The contrast improvement offered by the implementation of plasma mirrors was seen to increase the maximum energy of laser accelerated protons from targets thicker than 1 micrometer. In addition, the plasma mirrors allowed nanoscale targets to survive pre-pulse and pedestal features and support the production of ion beams. Proton spectra show that ions were accelerated to greater maximum energies from nanoscale targets than from more traditional micron-scale targets. This effect can be attributed to a reduction in the target pre-plasma scale length upon the introduction of plasma mirrors. These results indicate that the manipulation of target properties and laser contrast can significantly affect the interaction between an ultrahigh intensity laser and a target.

Published

2014

41. A TNSA based platform for deuterium and tritium beams to study nuclear reactions between light nuclei

Author

Schwemmlein, Arnold, Schröder, W. Udo, Schwemmlein, Arnold, and Schröder, W. Udo

Abstract

Thesis (Ph. D.)--University of Rochester. Departments of Chemistry, and Physics and Astronomy, 2021., A controllable tritium beam provides an invaluable tool for the study of nuclear reactions involving neutron rich nuclei such as 6He, 9 Li and 11Be. Other potential applications in the field of inertial confinement fusion (ICF) include independent measurements of the tritium-tritium (TT) reaction and triton-driven fast ignition. However, the handling of diffusive, radioactive tritium is very challenging for accelerator facilities. On the other hand, target normal sheath acceleration (TNSA) can produce beams with isolated, miniature (500x500x25µm³) converter targets, requiring only micro Curies of activity. The focus of this project was the development of such a TNSA-based triton beam platform. The TNSA experiments were conducted at the two LLE laser facilities Multi Terawatt (MTW) and OMEGA-EP (Extended Performance). While the aspects of TNSA were studied on the low energy (~20J), high repetition (20 min shot cycle) MTW system, the nuclear experiments were conducted on the high energy (1.25kJ) OMEGA-EP system. A central part of this work was the design and fabrication of deuterium- and tritiumdoped targets to be used in TNSA experiments. The loading procedures were continuously optimized using results from the MTW platform. From these experiments, it was found that exposure of the titanium target to high pressure (~950 Torr), high temperature (400°C) molecular deuterium maximizes the total deuterium yield of the targets. The laser energy has a strong impact on both the total deuterium yield and spectrum, with the higher laser energies accelerating more deuterons to higher energies. A major experimental result of this work was the manipulation of the deuteron spectra - by increasing the laser energy - from an exponential to an exponentially modified Gaussian shape, with maximum mean beam energies of 0.5 ± 0.2 MeV. A custom ion dynamics code was developed as part of this project to interpret this result. On OMEGA-EP, an exponential spectrum with mean 2.3 ± 2.3 MeV and