Your search keyword '"Batani, D"' showing total 1,228 results

1. Laser initiated p-11B fusion reactions in petawatt high-repetition-rates laser facilities

Author

Scisciò, M., Petringa, G., Zhu, Z., Rodrigues, M. R. D., Alonzo, M., Andreoli, P. L., Filippi, F., Consoli, Fe., Huault, M., Raffestin, D., Molloy, D., Larreur, H., Singappuli, D., Carriere, T., Verona, C., Nicolai, P., McNamee, A., Ehret, M., Filippov, E., Lera, R., Pérez-Hernández, J. A., Agarwal, S., Krupka, M., Singh, S., Istokskaia, V., Lattuada, D., La Cognata, M., Guardo, G. L., Palmerini, S., Rapisarda, G., Batani, K., Cipriani, M., Cristofari, G., Di Ferdinando, E., Di Giorgio, G., De Angelis, R., Giulietti, D., Xu, J., Volpe, L., Rodríguez-Frías, M. D., Giuffrida, L., Margarone, D., Batani, D., Cirrone, G. A. P., Bonasera, A., and Consoli, Fa.

Subjects

Physics - Plasma Physics

Abstract

Driving the nuclear fusion reaction p+11B -> 3 alpha + 8.7 MeV in laboratory conditions, by interaction between high-power laser pulses and matter, has become a popular field of research, due to numerous applications that it can potentially allow: an alternative to deuterium-tritium (DT) for fusion energy production, astrophysics studies and alpha-particle generation for medical treatments. A possible scheme for laser-driven p-11B reactions is to direct a beam of laser-accelerated protons onto a boron sample (the so-called 'pitcher-catcher' scheme). This technique was successfully implemented on large, energetic lasers, yielding hundreds of joules per shot at low repetition. We present here a complementary approach, exploiting the high-repetition rate of the VEGA III petawatt laser at CLPU (Spain), aiming at accumulating results from many interactions at much lower energy, for better controlling the parameters and the statistics of the measurements. Despite a moderate energy per pulse, our experiment allowed exploring the laser-driven fusion process with tens (up to hundreds) of laser shots. The experiment provided a clear signature of the produced reactions and of the fusion products, accumulated over many shots, leading to an improved optimization of the diagnostic for these experimental campaigns In this paper we discuss the effectiveness of the laser-driven p-11B fusion in the pitcher-catcher scheme, at high-repetition rate, addressing the challenges of this experimental scheme and highlighting its critical aspects. Our proposed methodologies allow evaluating the performance of this scheme for laser-driven alpha particle production and can be adapted to high-repetition rate laser facilities with higher energy and intensity.

Published

2024

2. Radioisotopes production using lasers: from basic science to applications

Author

Rodrigues, M. R. D., Bonasera, A., Scisciò, M., Pérez-Hernández, J. A., Ehret, M., Filippi, F., Andreoli, P. L., Huault, M., Larreur, H., Singappuli, D., Molloy, D., Raffestin, D., Alonzo, M., Rapisarda, G. G., Lattuada, D., Guardo, G. L., Verona, C., Consoli, Fe., Petringa, G., McNamee, A., La Cognata, M., Palmerini, S., Carriere, T., Cipriani, M., Di Giorgio, G., Cristofari, G., De Angelis, R., Cirrone, G. A. P., Margarone, D., Giuffrida, L., Batani, D., Nicolai, P., Batani, K., Lera, R., Volpe, L., Giulietti, D., Agarwal, S., Krupka, M., Singh, S., and Consoli, Fa.

Subjects

Nuclear Experiment, Physics - Applied Physics, Physics - Plasma Physics

Abstract

Laser technologies improved after the understanding of the Chirped Pulse Amplification (CPA) which allows energetic laser beams to be compressed to tens of femtosecond (fs) pulse durations and focused to few $\mu$m. Protons of tens of MeV can be accelerated using for instance the Target Normal Sheath Acceleration (TNSA) method and focused on secondary targets. In such conditions, nuclear reactions can occur and radioisotopes relevant for medical purposes be produced. High repetition lasers can be used to produce enough isotopes for medical applications. This route is competitive to conventional methods mostly based on accelerators. In this paper we study the production of $^{67}$Cu, $^{63}$Zn, $^{18}$F and $^{11}$C currently used in positron emission tomography (PET) and other applications. At the same time, we study the reaction $^{10}$B(p,$\alpha$)$^{7}$Be and $^{70}$Zn(p,4n)$^{67}$Ga to put further constraints to the proton distributions at different angles and to the reaction $^{11}$B(p,$\alpha$)$^{8}$Be relevant for energy production. The experiment was performed at the 1 petawatt (PW) laser facility at Vega III located in Salamanca-Spain. Angular distributions of radioisotopes in the forward (with respect to the laser direction) and backward directions were measured using a High Purity Germanium Detector (HPGE). Our results are reasonably reproduced by the numerical estimates following the approach of Kimura et al. (NIMA637(2011)167)

Published

2023

3. A cylindrical implosion platform for the study of highly magnetized plasmas at LMJ

Author

Pérez-Callejo, G., Vlachos, C., Walsh, C. A., Florido, R., Bailly-Grandvaux, M., Vaisseau, X., Suzuki-Vidal, F., McGuffey, C., Beg, F. N., Bradford, P., Ospina-Bohórquez, V., Batani, D., Raffestin, D., Colaïtis, A., Tikhonchuk, V., Casner, A., Koenig, M., Albertazzi, B., Fedosejevs, R., Woolsey, N., Ehret, M., Debayle, A., Loiseau, P., Calisti, A., Ferri, S., Honrubia, J., Kingham, R., Mancini, R. C., Gigosos, M. A., and Santos, J. J.

Subjects

Physics - Plasma Physics, High Energy Physics - Experiment

Abstract

Investigating the potential benefits of the use of magnetic fields in Inertial Confinement Fusion (ICF) experiments has given rise to new experimental platforms like the Magnetized Liner Inertial Fusion (MagLIF) approach at the Z-machine (Sandia National Laboratories), or its laser-driven equivalent at OMEGA (Laboratory for Laser Energetics). Implementing these platforms at MJ-scale laser facilities, such as the Laser MegaJoule (LMJ) or the National Ignition Facility (NIF), is crucial to reaching self-sustained nuclear fusion and enlarges the level of magnetization that can be achieved through a higher compression. In this paper, we present a complete design of an experimental platform for magnetized implosions using cylindrical targets at LMJ. A seed magnetic field is generated along the axis of the cylinder using laser-driven coil targets, minimizing debris and increasing diagnostic access compared with pulsed power field generators. We present a comprehensive simulation study of the initial B-field generated with these coil targets, as well as 2-dimensional extended magneto-hydrodynamics (MHD) simulations showing that a 5T initial B-field is compressed up to 25kT during the implosion. Under these circumstances, the electrons become magnetized, which severely modifies the plasma conditions at stagnation. In particular, in the hot spot the electron temperature is increased (from 1keV to 5keV) while the density is reduced (from 40gcc to 7gcc). We discuss how these changes can be diagnosed using X-ray imaging and spectroscopy, and particle diagnostics. We propose the simultaneous use of two dopants in the fuel (Ar and Kr) to act as spectroscopic tracers. We show that this introduces an effective spatial resolution in the plasma which permits an unambiguous observation of the B-field effects. Additionally, we present a plan for future experiments of this kind at LMJ.

Published

2022

4. Experimental capabilities of the LMJ-PETAL facility

Author

Cayzac, W., Boutoux, G., Brygoo, S., Denoeud, A., Depierreux, S., Tassin, V., Albert, F., Alozy, E., Baccou, C., Batani, D., Blanchot, N., Bonneau, M., Bonnefille, M., Botrel, R., Bowen, C., Bradford, P., Brochier, M., Caillaud, T., Chaleil, A., Chardavoine, S., Chollet, C., Courtois, C., Darbon, S., Davoine, X., Debesset, S., Denis, V., Diaz, R., Dizière, A., Du Jeu, R., Duchastenier, W., Dupré, P., Duval, A., Esnault, C., Etchessahar, B., Ferri, M., Fuchs, J., Geoffray, I., Gremillet, L., Grolleau, A., D’Humières, E., Jalinaud, T., Laffite, S., Lafon, M., Lagache, M.A., Landoas, O., Lantuejoul, I., Le-Deroff, L., Le Tacon, S., Leidinger, J.P., Lelièvre, R., Liberatore, S., Mahieu, B., Masson-Laborde, P.E., Meyer, C., Miquel, J.L., Parreault, R., Philippe, F., Prévot, V., Prunet, P., Raphaël, O., Reverdin, C., Ribotte, L., Riquier, R., Rousseaux, C., Sary, G., Soullié, G., Sozet, M., Ta-Phuoc, K., Trela, J., Trauchessec, V., Vaisseau, X., Vauzour, B., Villette, B., and Lefebvre, E.

Published

2024

5. Investigation on the origin of hot electrons in laser plasma interaction at shock ignition intensities

Author

Cristoforetti, G., Baffigi, F., Batani, D., Dudzak, R., Fedosejevs, R., Filippov, E. D., Gajdos, P., Juha, L., Khan, M., Koester, P., Krus, M., Mancelli, D., Martynenko, A. S., Nicolai, Ph., Pikuz, S. A., Renner, O., Tentori, A., Volpe, L., Woolsey, N., Zeraouli, G., and Gizzi, L. A.

Published

2023

6. Observation and modelling of Stimulated Raman Scattering driven by an optically smoothed laser beam in experimental conditions relevant for Shock Ignition

Author

Cristoforetti, G., Huller, S., Koester, P., Antonelli, L., Atzeni, S., Baffigi, F., Batani, D., Baird, C., Booth, N., Galimberti, M., Glize, K., Heron, A., Khan, M., Loiseau, P., Mancelli, D., Notley, M., Oliveira, P., Renner, O., Smid, M., Schiavi, A., Tran, G., Woolsey, N. C., and Gizzi, L. A.

Subjects

Physics - Plasma Physics

Abstract

We report results and modelling of an experiment performed at the TAW Vulcan laser facility, aimed at investigating laser-plasma interaction in conditions which are of interest for the Shock Ignition scheme to Inertial Confinement Fusion, i.e. laser intensity higher than 10^16 W/cm2 impinging on a hot (T > 1 keV), inhomogeneous and long scalelength preformed plasma. Measurements show a significant SRS backscattering (4 - 20% of laser energy) driven at low plasma densities and no signatures of TPD/SRS driven at the quarter critical density region. Results are satisfactorily reproduced by an analytical model accounting for the convective SRS growth in independent laser speckles, in conditions where the reflectivity is dominated by the contribution from the most intense speckles, where SRS gets saturated. Analytical and kinetic simulations well reproduce the onset of SRS at low plasma densities in a regime strongly affected by non linear Landau damping and by filamentation of the most intense laser speckles. The absence of TPD/SRS at higher densities is explained by pump depletion and plasma smoothing driven by filamentation. The prevalence of laser coupling in the low density profile justifies the low temperature measured for hot electrons (7 - 12 keV), well reproduced by numerical simulations.

Published

2021

7. A quasi-monoenergetic short time duration compact proton source for probing high energy density states of matter

Author

Apiñaniz, J. I., Malko, S., Fedosejevs, R., Cayzac, W., Vaisseau, X., de Luis, D., Gatti, G., McGuffey, C., Bailly-Grandvaux, M., Bhutwala, K., Ospina-Bohorquez, V., Balboa, J., Santos, J. J., Batani, D., Beg, F., Roso, L., Perez-Hernandez, J. A., and Volpe, L.

Subjects

Physics - Plasma Physics, High Energy Physics - Experiment

Abstract

We report on the development of a highly directional, narrow energy band, short time duration proton beam operating at high repetition rate, suitable for measurements of stopping power in high energy density plasmas as well as other applications. The protons are generated with an ultrashort-pulse laser interacting with a solid target and converted to a pencil-like narrow-band beam using a compact magnet-based energy selector. We experimentally demonstrate the production of a proton beam with an energy of 500 keV and energy spread well below 10%, and a pulse duration of 260 ps. The energy loss of this beam is measured in a 2 ${\mu}$m thick solid Mylar target and found to be in within 1% of theoretical predictions. The short time duration of the proton pulse makes it particularly well suited for applications involving the probing of highly transient plasma states produced in laser-matter interaction experiments, in particular measurements of proton stopping power.

Published

2020

8. Nuclear physics midterm plan at LNS

Author

Agodi, C., Cappuzzello, F., Cardella, G., Cirrone, G. A. P., De Filippo, E., Di Pietro, A., Gargano, A., La Cognata, M., Mascali, D., Milluzzo, G., Nania, R., Petringa, G., Pidatella, A., Pirrone, S., Pizzone, R. G., Rapisarda, G. G., Sergi, M. L., Tudisco, S., Valiente-Dobón, J. J., Vardaci, E., Abramczyk, H., Acosta, L., Adsley, P., Amaducci, S., Banerjee, T., Batani, D., Bellone, J., Bertulani, C., Biri, S., Bogachev, A., Bonanno, A., Bonasera, A., Borcea, C., Borghesi, M., Bortolussi, S., Boscolo, D., Brischetto, G. A., Burrello, S., Busso, M., Calabrese, S., Calinescu, S., Calvo, D., Capirossi, V., Carbone, D., Cardinali, A., Casini, G., Catalano, R., Cavallaro, M., Ceccuzzi, S., Celona, L., Cherubini, S., Chieffi, A., Ciraldo, I., Ciullo, G., Colonna, M., Cosentino, L., Cuttone, G., D’Agata, G., De Gregorio, G., Degl’Innocenti, S., Delaunay, F., Di Donato, L., Di Nitto, A., Dickel, T., Doria, D., Ducret, J. E., Durante, M., Esposito, J., Farrokhi, F., Fernandez Garcia, J. P., Figuera, P., Fisichella, M., Fulop, Z., Galatá, A., Galaviz Redondo, D., Gambacurta, D., Gammino, S., Geraci, E., Gizzi, L., Gnoffo, B., Groppi, F., Guardo, G. L., Guarrera, M., Hayakawa, S., Horst, F., Hou, S. Q., Jarota, A., José, J., Kar, S., Karpov, A., Kierzkowska-Pawlak, H., Kiss, G. G., Knyazheva, G., Koivisto, H., Koop, B., Kozulin, E., Kumar, D., Kurmanova, A., La Rana, G., Labate, L., Lamia, L., Lanza, E. G., Lay, J. A., Lattuada, D., Lenske, H., Limongi, M., Lipoglavsek, M., Lombardo, I., Mairani, A., Manetti, S., Marafini, M., Marcucci, L., Margarone, D., Martorana, N. S., Maunoury, L., Mauro, G. S., Mazzaglia, M., Mein, S., Mengoni, A., Milin, M., Mishra, B., Mou, L., Mrazek, J., Nadtochy, P., Naselli, E., Nicolai, P., Novikov, K., Oliva, A. A., Pagano, A., Pagano, E. V., Palmerini, S., Papa, M., Parodi, K., Patera, V., Pellumaj, J., Petrone, C., Piantelli, S., Pierroutsakou, D., Pinna, F., Politi, G., Postuma, I., Prajapati, P., Prada Moroni, P. G., Pupillo, G., Raffestin, D., Racz, R., Reidel, C.-A., Rifuggiato, D., Risitano, F., Rizzo, F., Roca Maza, X., Romano, S., Roso, L., Rotaru, F., Russo, A. D., Russotto, P., Saiko, V., Santonocito, D., Santopinto, E., Sarri, G., Sartirana, D., Schuy, C., Sgouros, O., Simonucci, S., Sorbello, G., Soukeras, V., Spartá, R., Spatafora, A., Stanoiu, M., Taioli, S., Tessonnier, T., Thirolf, P., Tognelli, E., Torresi, D., Torrisi, G., Trache, L., Traini, G., Trimarchi, M., Tsikata, S., Tumino, A., Tyczkowski, J., Yamaguchi, H., Vercesi, V., Vidana, I., Volpe, L., and Weber, U.

Published

2023

9. Fast electron transport dynamics and energy deposition in magnetized, imploded cylindrical plasma

Author

Kawahito, D, Bailly-Grandvaux, M, Dozires, M, McGuffey, C, Forestier-Colleoni, P, Peebles, J, Honrubia, JJ, Khiar, B, Hansen, S, Tzeferacos, P, Wei, MS, Krauland, CM, Gourdain, P, Davies, JR, Matsuo, K, Fujioka, S, Campbell, EM, Santos, JJ, Batani, D, Bhutwala, K, Zhang, S, and Beg, FN

Subjects

Information and Computing Sciences, Engineering, Applied Computing, Physical Sciences, Affordable and Clean Energy, ICF, fast electrons, compression, General Science & Technology

Abstract

Inertial confinement fusion approaches involve the creation of high-energy-density states through compression. High gain scenarios may be enabled by the beneficial heating from fast electrons produced with an intense laser and by energy containment with a high-strength magnetic field. Here, we report experimental measurements from a configuration integrating a magnetized, imploded cylindrical plasma and intense laser-driven electrons as well as multi-stage simulations that show fast electrons transport pathways at different times during the implosion and quantify their energy deposition contribution. The experiment consisted of a CH foam cylinder, inside an external coaxial magnetic field of 5 T, that was imploded using 36 OMEGA laser beams. Two-dimensional (2D) hydrodynamic modelling predicts the CH density reaches [Formula: see text], the temperature reaches 920 eV and the external B-field is amplified at maximum compression to 580 T. At pre-determined times during the compression, the intense OMEGA EP laser irradiated one end of the cylinder to accelerate relativistic electrons into the dense imploded plasma providing additional heating. The relativistic electron beam generation was simulated using a 2D particle-in-cell (PIC) code. Finally, three-dimensional hybrid-PIC simulations calculated the electron propagation and energy deposition inside the target and revealed the roles the compressed and self-generated B-fields play in transport. During a time window before the maximum compression time, the self-generated B-field on the compression front confines the injected electrons inside the target, increasing the temperature through Joule heating. For a stronger B-field seed of 20 T, the electrons are predicted to be guided into the compressed target and provide additional collisional heating. This article is part of a discussion meeting issue 'Prospects for high gain inertial fusion energy (part 2)'.

Published

2021

10. A quasi-monoenergetic short time duration compact proton source for probing high energy density states of matter

Author

Apiñaniz, JI, Malko, S, Fedosejevs, R, Cayzac, W, Vaisseau, X, de Luis, D, Gatti, G, McGuffey, C, Bailly-Grandvaux, M, Bhutwala, K, Ospina-Bohorquez, V, Balboa, J, Santos, JJ, Batani, D, Beg, F, Roso, L, Perez-Hernandez, JA, and Volpe, L

Subjects

Nuclear and Plasma Physics, Synchrotrons and Accelerators, Physical Sciences, Affordable and Clean Energy

Abstract

We report on the development of a highly directional, narrow energy band, short time duration proton beam operating at high repetition rate. The protons are generated with an ultrashort-pulse laser interacting with a solid target and converted to a pencil-like narrow-band beam using a compact magnet-based energy selector. We experimentally demonstrate the production of a proton beam with an energy of 500 keV and energy spread well below 10[Formula: see text], and a pulse duration of 260 ps. The energy loss of this beam is measured in a 2 [Formula: see text]m thick solid Mylar target and found to be in good agreement with the theoretical predictions. The short time duration of the proton pulse makes it particularly well suited for applications involving the probing of highly transient plasma states produced in laser-matter interaction experiments. This proton source is particularly relevant for measurements of the proton stopping power in high energy density plasmas and warm dense matter.

Published

2021

11. Pump-Depletion Dynamics and Saturation of Stimulated Brillouin Scattering in Shock Ignition Relevant Experiments

Author

Zhang, S., Li, J., Krauland, C. M., Beg, F. N., Muller, S., Theobald, W., Palastro, J., Filkins, T., Turnbull, D., Haberberger, D., Ren, C., Betti, R., Stoeckl, C., Campbell, E. M., Trela, J., Batani, D., Scott, R., and Wei, M. S.

Subjects

Physics - Plasma Physics

Abstract

As an alternative inertial confinement fusion scheme with predicted high energy gain and more robust designs, shock ignition requires a strong converging shock driven by a shaped pulse with a high-intensity spike at the end to ignite a pre-compressed fusion capsule. Understanding nonlinear laser-plasma instabilities in shock ignition conditions is crucial to assess and improve the laser-shock energy coupling. Recent experiments conducted on the OMEGA-EP laser facility have for the first time demonstrated that such instabilities can $\sim$100\% deplete the first 0.5 ns of the high-intensity laser pump. Analysis of the observed laser-generated blast wave suggests that this pump-depletion starts at 0.01--0.02 critical density and progresses to 0.1--0.2 critical density. This pump-depletion is also confirmed by the time-resolved stimulated Raman backscattering spectra. The dynamics of the pump-depletion can be explained by the breaking of ion-acoustic waves in stimulated Brillouin scattering. Such strong pump-depletion would inhibit the collisional laser energy absorption but may benefit the generation of hot electrons with moderate temperatures for electron shock ignition [Shang et al. Phys. Rev. Lett. 119 195001 (2017)].

Published

2019

12. Enhanced relativistic-electron beam collimation using two consecutive laser pulses

Author

Malko, S., Vaisseau, X., Perez, F., Batani, D., Curcio, A., Ehret, M., Honrubia, J. J., Jakubowska, K., Morace, A., Santos, J. J., and Volpe, L.

Subjects

Physics - Plasma Physics

Abstract

The double laser pulse approach to relativistic electron beam (REB) collimation has been investigated at the LULI-ELFIE facility. In this scheme, the magnetic field generated by the first laser-driven REB is used to guide a second delayed REB. We show how electron beam collimation can be controlled by properly adjusting laser parameters. By changing the ratio of focus size and the delay time between the two pulses we found a maximum of electron beam collimation clearly dependent on the focal spot size ratio of the two laser pulses and related to the magnetic field dynamics. Cu-K alpha and CTR imaging diagnostics were implemented to evaluate the collimation effects on the respectively low energy (< 100 keV) and high energy (> MeV) components of the REB.

Published

2019

13. Semi-analytical approaches to study hot electrons in the shock ignition regime

Author

Afshari, M., Antonelli, L., Barbato, F., Folpini, G., Jakubowska, K., Krousky, E., Renner, O., Smid, M., and Batani, D.

Subjects

Physics - Plasma Physics

Abstract

Hot electrons role in shock generation and energy deposition to hot dense core is crucial for the shock ignition scheme implying the need for their characterization at laser intensities of interest for shock ignition. In this paper we analyze the experimental results obtained at the PALS laboratory and provide an estimation of hot electrons temperature and conversion efficiency using a semi analytical approach, including Harrach-Kidder's model., Comment: Has been accepted in Physics of Plasma journal

Published

2018

14. Development of an adjustable Kirkpatrick-Baez microscope for laser driven x-ray sources at CLPU

Author

Zeraouli, G., gatti, G., Longman, A., Perez, J. A., Arana, D., Batani, D., Volpe, L., Roso, L., and Fedosejevs, R.

Subjects

Physics - Instrumentation and Detectors, Physics - Applied Physics

Abstract

A promising prototype of a highly adjustable Kirkpatrick-Baez (KB) microscope has been designed, built and tested in a number of laser driven x-ray experiments using the high power (200TW) VEGA-2 laser system of the Spanish Centre for Pulsed Lasers (CLPU). The presented KB version consists of two, perpendicularly mounted, 500{\mu}m thick Silicon wafers, coated with a few tens of nm layer of Platinum unlike the conventional, coated, millimetre thick glass substrates, affording more bending flexibility and large adjustment range. According to simulations, and based on total external reflection, this KB offers a broad-band multi-keV reflection spectra, allowing more spectral tunablity than conventional Bragg crystals. In addition to be vacuum compatible, the prototype is characterised by a relatively small size (21cm x 31cm x 27cm) and permits remote control and modification of both the radius of curvature (down to 10m) and the grazing incidence angle (up to 60mrad). A few examples of focusing performance tests, limitations and experimental campaign results are discussed.

Published

2018

15. X-ray phase-contrast imaging for laser-induced shock waves

Author

Antonelli, L., Barbato, F., Neumayer, P., Mancelli, D., Trela, J., Zeaoruli, G., Bagnoud, V., Brabetz, C., Zielbauer, B., Borm, B., Bradford, P., Woolsey, N., and Batani, D.

Subjects

Physics - Plasma Physics

Abstract

X-ray phase-contrast imaging (XPCI) is a versatile technique with wide-ranging applications, particularly in the fields of biology and medicine. Where X-ray absorption radiography requires high density ratios for effective imaging, XPCI is more sensitive to the density gradients inside a material. In this letter, we apply XPCI to the study of laser-driven shockc waves. We used two laser beams from the Petawatt High-Energy Laser for Heavy Ion EXperiments (PHELIX) at GSI: one to launch a shock wave and the other to generate an X-ray source for XPCI. Our results suggest that this technique is suitable for the study of warm dense matter (WDM), inertial confinement fusion (ICF) and laboratory astrophysics.

Published

2018

16. Laser-driven strong magnetostatic fields with applications to charged beam transport and magnetized high energy-density physics

Author

Santos, J. J., Bailly-Grandvaux, M., Ehret, M., Arefiev, A. V., Batani, D., Beg, F. N., Calisti, A., Ferri, S., Florido, R., Forestier-Colleoni, P., Fujioka, S., Gigosos, M. A., Giuffrida, L., Gremillet, L., Honrubia, . J., Kojima, S., Korneev, Ph., Law, K. F. F., Marquès, J. -R., Morace, A., Mossé, C., Peyrusse, O., Rose, S., Roth, M., Sakata, S., Schaumann, G., Suzuki-Vidal, F., Tikhonchuk, V. T., Toncian, T., Woolsey, N., and Zhang, Z.

Subjects

Physics - Plasma Physics

Abstract

Powerful laser-plasma processes are explored to generate discharge currents of a few $100\,$kA in coil targets, yielding magnetostatic fields (B-fields) in excess of $0.5\,$kT. The quasi-static currents are provided from hot electron ejection from the laser-irradiated surface. According to our model, describing qualitatively the evolution of the discharge current, the major control parameter is the laser irradiance $I_{\mathrm{las}}\lambda_{\mathrm{las}}^2$. The space-time evolution of the B-fields is experimentally characterized by high-frequency bandwidth B-dot probes and by proton-deflectometry measurements. The magnetic pulses, of ns-scale, are long enough to magnetize secondary targets through resistive diffusion. We applied it in experiments of laser-generated relativistic electron transport into solid dielectric targets, yielding an unprecedented 5-fold enhancement of the energy-density flux at $60 \,\mathrm{\mu m}$ depth, compared to unmagnetized transport conditions. These studies pave the ground for magnetized high-energy density physics investigations, related to laser-generated secondary sources of radiation and/or high-energy particles and their transport, to high-gain fusion energy schemes and to laboratory astrophysics., Comment: 11 pages, 7 figures, invited APS

Published

2017

17. Proton stopping measurements at low velocity in warm dense carbon

Author

Malko, S., Cayzac, W., Ospina-Bohórquez, V., Bhutwala, K., Bailly-Grandvaux, M., McGuffey, C., Fedosejevs, R., Vaisseau, X., Tauschwitz, An., Apiñaniz, J. I., De Luis Blanco, D., Gatti, G., Huault, M., Hernandez, J. A. Perez, Hu, S. X., White, A. J., Collins, L. A., Nichols, K., Neumayer, P., Faussurier, G., Vorberger, J., Prestopino, G., Verona, C., Santos, J. J., Batani, D., Beg, F. N., Roso, L., and Volpe, L.

Published

2022

18. Experimental measurements of gamma-photon production and estimation of electron/positron production on the PETAL laser facility.

Author

Brun, F., Ribotte, L., Boutoux, G., Davoine, X., Masson-Laborde, P. E., Sentoku, Y., Iwata, N., Blanchot, N., Batani, D., Lantuéjoul, I., Lecherbourg, L., Rosse, B., Rousseaux, C., Vauzour, B., Raffestin, D., D'Humières, E., and Ribeyre, X.

Subjects

LASER pulses, POSITRONIUM, POSITRONS, DISTRIBUTION (Probability theory), HOT carriers, MONTE Carlo method, LASERS

Abstract

This article reports the first measurements of high-energy photons produced with the high-intensity PETawatt Aquitaine Laser (PETAL) laser. The experiments were performed during the commissioning of the laser. The laser had an energy of about 400 J, an intensity of 8 × 1018 W cm−2, and a pulse duration of 660 fs (FWHM). It was shot at a 2 mm-thick solid tungsten target. The high-energy photons were produced mainly from the bremsstrahlung process for relativistic electrons accelerated inside a plasma generated on the front side of the target. This paper reports measurements of electrons, protons and photons. Hot electrons up to ≈35 MeV with a few-MeV temperature were recorded by a spectrometer, called SESAME (Spectre ÉlectronS Angulaire Moyenne Énergie). K- and L-shells were clearly detected by a photon spectrometer called SPECTIX (Spectromètre Petal à Cristal en TransmIssion pour le rayonnnement X). High-energy photons were diagnosed by CRACC-X (Cassette de RAdiographie Centre Chambre-rayonnement X), a bremsstrahlung cannon. Bremsstrahlung cannon analysis is strongly dependent on the hypothesis adopted for the spectral shape. Different shapes can exhibit similar reproductions of the experimental data. To eliminate dependence on the shape hypothesis and to facilitate analysis of the data, simulations of the interaction were performed. To model the mechanisms involved, a simulation chain including hydrodynamic, particle-in-cell, and Monte Carlo simulations was used. The simulations model the preplasma generated at the front of the target by the PETAL laser prepulse, the acceleration of electrons inside the plasma, the generation of MeV-range photons from these electrons, and the response of the detector impacted by the energetic photon beam. All this work enabled reproduction of the experimental data. The high-energy photons produced have a large emission angle and an exponential distribution shape. In addition to the analysis of the photon spectra, positron production was also investigated. Indeed, if high-energy photons are generated inside the solid target, some positron/electron pairs may be produced by the Bethe–Heitler process. Therefore, the positron production achievable within the PETAL laser facility was quantified. To conclude the study, the possibility of creating electron/positron pairs through the linear Breit–Wheeler process with PETAL was investigated. [ABSTRACT FROM AUTHOR]

Published

2024

19. Borane (B m H n ), Hydrogen rich, Proton Boron fusion fuel materials for high yield laser-driven Alpha sources

Author

Turcu, I.C.E., primary, Margarone, D., additional, Giuffrida, L., additional, Picciotto, A., additional, Spindloe, C., additional, Robinson, A.P.L., additional, and Batani, D., additional

Published

2024

20. Guiding of relativistic electron beams in dense matter by longitudinally imposed strong magnetic fields

Author

Bailly-Grandvaux, M., Santos, J. J., Bellei, C., Forestier-Colleoni, P., Fujioka, S., Giuffrida, L., Honrubia, J. J., Batani, D., Bouillaud, R., Chevrot, M., Cross, J. E., Crowston, R., Dorard, S., Dubois, J. -L., Ehret, M., Gregori, G., Hulin, S., Kojima, S., Loyez, E., Marques, J. -R., Morace, A., Nicolai, Ph., Roth, M., Sakata, S., Schaumann, G., Serres, F., Servel, J., Tikhonchuk, V. T., Woolsey, N., and Zhang, Z.

Subjects

Physics - Plasma Physics

Abstract

High-energy-density flows through dense matter are needed for effective progress in the production of laser-driven intense sources of energetic particles and radiation, in driving matter to extreme temperatures creating state regimes relevant for planetary or stellar science as yet inaccessible at the laboratory scale, or in achieving high-gain laser-driven thermonuclear fusion. When interacting at the surface of dense (opaque) targets, intense lasers accelerate relativistic electron beams which transport a significant fraction of the laser energy into the target depth. However, the overall laser-to-target coupling efficiency is impaired by the large divergence of the electron beam, intrinsic to the laser-plasma interaction. By imposing a longitudinal 600T laser-driven magnetic-field, our experimental results show guided >10MA-current of MeV-electrons in solid matter. Due to the applied magnetic field, the transported energy-density and the peak background electron temperature at the 60micron-thick targets rear surface rise by factors 5, resulting from unprecedentedly efficient guiding of relativistic electron currents., Comment: 11 pages, 7 figures

Published

2016

21. Laser-driven platform for generation and characterization of strong quasi-static magnetic fields

Author

Santos, J. J., Bailly-Grandvaux, M., Giuffrida, L., Forestier-Colleoni, P., Fujioka, S., Zhang, Z., Korneev, Ph., Bouillaud, R., Dorard, S., Batani, D., Chevrot, M., Cross, J., Crowston, R., Dubois, J. -L., Gazave, J., Gregori, G., d'Humières, E., Hulin, S., Ishihara, K., Kojima, S., Loyez, E., Marquès, J. -R., Morace, A., Nicolaï, Ph., Peyrusse, O., Poyé, A., Raffestin, D., Ribolzi, J., Roth, M., Schaumann, G., Serres, F., Tikhonchuk, V. T., Vacar, Ph., and Woolsey, N.

Subjects

Physics - Plasma Physics

Abstract

Quasi-static magnetic-fields up to $800\,$T are generated in the interaction of intense laser pulses ($500\,$J, $1\,$ns, $10^{17}\,$W/cm$^2$) with capacitor-coil targets of different materials. The reproducible magnetic-field peak and rise-time, consistent with the laser pulse duration, were accurately inferred from measurements with GHz-bandwidth inductor pickup coils (B-dot probes). Results from Faraday rotation of polarized optical laser light and deflectometry of energetic proton beams are consistent with the B-dot probe measurements at the early stages of the target charging, up to $t\approx 0.35\,$ns, and then are disturbed by radiation and plasma effects. The field has a dipole-like distribution over a characteristic volume of $1\,$mm$^3$, which is coherent with theoretical expectations. These results demonstrate a very efficient conversion of the laser energy into magnetic fields, thus establishing a robust laser-driven platform for reproducible, well characterized, generation of quasi-static magnetic fields at the kT-level, as well as for magnetization and accurate probing of high-energy-density samples driven by secondary powerful laser or particle beams., Comment: 16 pages, 7 figures

Published

2015

22. Preliminary results from the LMJ-PETAL experiment on hot electrons characterization in the context of shock ignition

Author

Baton, S.D., Colaïtis, A., Rousseaux, C., Boutoux, G., Brygoo, S., Jacquet, L., Koenig, M., Batani, D., Casner, A., Bel, E. Le, Raffestin, D., Tentori, A., Tikhonchuk, V., Trela, J., Reverdin, C., Le-Deroff, L., Theobald, W., Cristoforetti, G., Gizzi, L.A., Koester, P., Labate, L., and Shigemori, K.

Published

2020

23. Multi-GeV Electron Spectrometer

Author

Faccini, R., Anelli, F., Bacci, A., Batani, D., Bellaveglia, M., Benocci, R., Benedetti, C., Cacciotti, L., Cecchetti, C. A., Clozza, A., Cultrera, L., Di~Pirro, G., Drenska, N., Ferrario, M., Filippetto, D., Fioravanti, S., Gallo, A., Gamucci, A., Gatti, G., Ghigo, A., Giulietti, A., Giulietti, D., Gizzi, L. A., Koester, P., Labate, L., Levato, T., Lollo, V., Londrillo, P., Martellotti, S., Pace, E., Patack, N., Rossi, A., Tani, F., Serafini, L., Turchetti, G., Vaccarezza, C., and Valente, P.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The advance in laser plasma acceleration techniques pushes the regime of the resulting accelerated particles to higher energies and intensities. In particular the upcoming experiments with the FLAME laser at LNF will enter the GeV regime with almost 1pC of electrons. From the current status of understanding of the acceleration mechanism, relatively large angular and energy spreads are expected. There is therefore the need to develop a device capable to measure the energy of electrons over three orders of magnitude (few MeV to few GeV) under still unknown angular divergences. Within the PlasmonX experiment at LNF a spectrometer is being constructed to perform these measurements. It is made of an electro-magnet and a screen made of scintillating fibers for the measurement of the trajectories of the particles. The large range of operation, the huge number of particles and the need to focus the divergence present unprecedented challenges in the design and construction of such a device. We will present the design considerations for this spectrometer and the first results from a prototype., Comment: 7 pages, 6 figures, submitted to NIM A

Published

2010

24. Future for Inertial Fusion Energy in Europe: A roadmap

Author

Batani, D., primary, Colaïtis, A., additional, Consoli, F., additional, Danson, C. N., additional, Gizzi, L. A., additional, Honrubia, J. J., additional, Kühl, T., additional, Le Pape, S., additional, Miquel, J.-L., additional, Perlado, J. M., additional, Scott, R. H. H., additional, Tatarakis, M., additional, Tikhonchuk, V., additional, and Volpe, L., additional

Published

2023

25. Characterization of hot electrons generated by laser–plasma interaction at shock ignition intensities

Author

Filippov, E. D., primary, Khan, M., additional, Tentori, A., additional, Gajdos, P., additional, Martynenko, A. S., additional, Dudzak, R., additional, Koester, P., additional, Zeraouli, G., additional, Mancelli, D., additional, Baffigi, F., additional, Gizzi, L. A., additional, Pikuz, S. A., additional, Nicolaï, Ph.D., additional, Woolsey, N. C., additional, Fedosejevs, R., additional, Krus, M., additional, Juha, L., additional, Batani, D., additional, Renner, O., additional, and Cristoforetti, G., additional

Published

2023

26. Optical Time-Resolved Diagnostics of Laser-Produced Plasmas

Author

Batani, D., Santos, J., Forestier-Colleoni, P., Mancelli, D., Ehret, M., Trela, J., Morace, A., Jakubowska, K., Antonelli, L., del Sorbo, D., Manclossi, M., and Veltcheva, M.

Published

2019

27. Effects of hydrogen concentration in ablator material on stimulated Raman scattering, two-plasmon decay, and hot electrons for direct-drive inertial confinement fusion

Author

Kawasaki, K., primary, Cristoforetti, G., additional, Idesaka, T., additional, Hironaka, Y., additional, Tanaka, D., additional, Batani, D., additional, Fujioka, S., additional, Gizzi, L. A., additional, Hata, M., additional, Johzaki, T., additional, Katagiri, K., additional, Kodama, R., additional, Matsuo, S., additional, Nagatomo, H., additional, Nicolai, Ph., additional, Ozaki, N., additional, Sentoku, Y., additional, Takizawa, R., additional, Yogo, A., additional, Yamada, H., additional, and Shigemori, K., additional

Published

2023

28. Investigation on the origin of hot electrons in laser plasma interaction at shock ignition intensities

Author

Cristoforetti, G., primary, Baffigi, F., additional, Batani, D., additional, Dudzak, R., additional, Fedosejevs, R., additional, Filippov, E. D., additional, Gajdos, P., additional, Juha, L., additional, Khan, M., additional, Koester, P., additional, Krus, M., additional, Mancelli, D., additional, Martynenko, A. S., additional, Nicolai, Ph., additional, Pikuz, S. A., additional, Renner, O., additional, Tentori, A., additional, Volpe, L., additional, Woolsey, N., additional, Zeraouli, G., additional, and Gizzi, L. A., additional

Published

2023

29. Laser-plasma energetic particle production for aneutronic nuclear fusion experiments

Author

Giulietti, D., Andreoli, P., Batani, D., Bonasera, A., Boutoux, G., Burgy, F., Cipriani, M., Consoli, F., Cristofari, G., De Angelis, R., Di Giorgio, G., Ducret, J.E., Ingenito, F., Jakubowska, K., Verona, C., and Verona-Rinati, G.

Published

2017

30. Author Correction: Quantitative phase contrast imaging of a shock-wave with a laser-plasma based X-ray source

Author

Barbato, F., Atzeni, S., Batani, D., Bleiner, D., Boutoux, G., Brabetz, C., Bradford, P., Mancelli, D., Neumayer, P., Schiavi, A., Trela, J., Volpe, L., Zeraouli, G., Woolsey, N., and Antonelli, L.

Published

2020

31. Quantitative phase contrast imaging of a shock-wave with a laser-plasma based X-ray source

Author

Barbato, F., Atzeni, S., Batani, D., Bleiner, D., Boutoux, G., Brabetz, C., Bradford, P., Mancelli, D., Neumayer, P., Schiavi, A., Trela, J., Volpe, L., Zeraouli, G., Woolsey, N., and Antonelli, L.

Published

2019

32. Incubation models for under-threshold laser ablation with thermal dissipation

Author

Benocci, R., Batani, D., and Roman, H. E.

Published

2019

33. Multibeam laser–plasma interaction at the Gekko XII laser facility in conditions relevant for direct-drive inertial confinement fusion

Author

Cristoforetti, G., primary, Koester, P., additional, Atzeni, S., additional, Batani, D., additional, Fujioka, S., additional, Hironaka, Y., additional, Hüller, S., additional, Idesaka, T., additional, Katagiri, K., additional, Kawasaki, K., additional, Kodama, R., additional, Mancelli, D., additional, Nicolai, Ph., additional, Ozaki, N., additional, Schiavi, A., additional, Shigemori, K., additional, Takizawa, R., additional, Tamagawa, T., additional, Tanaka, D., additional, Tentori, A., additional, Umeda, Y., additional, Yogo, A., additional, and Gizzi, L. A., additional

Published

2023

34. Vanadium fine-structure K-shell electron impact ionization cross sections for fast-electron diagnostic in laser–solid experiments

Author

Palmeri, P., Quinet, P., and Batani, D.

Published

2015

35. Copper fine-structure K-shell electron impact ionization cross sections for fast-electron diagnostic in laser-solid experiments

Author

Palmeri, P., Quinet, P., and Batani, D.

Published

2015

36. Breakthrough at the NIF paves the way to inertial fusion energy

Author

Atzeni, S., Batani, D., Danson, C. N., Gizzi, L. A., Le Pape, S., Miquel, J-L., Perlado, M., Scott, R. H. H., Tatarakis, M., Tikhonchuk, V., and Volpe, L.

Subjects

plasma physics, inertial confinement fusion, General Physics and Astronomy, laser fusion, inertial fusion energy

Abstract

In August 2021, at the National Ignition Facility of the Lawrence Livermore National Laboratory in the USA, a 1.35 MJ fusion yield was obtained. It is a demonstration of the validity of the Inertial Confinement Fusion approach to achieve energy-efficient thermonuclear fusion in the laboratory. It is a historical milestone that the scientific community has achieved after decades of efforts.

Published

2022

37. 3D Monte-Carlo model to study the transport of hot electrons in the context of inertial confinement fusion. Part I

Author

Tentori, A., primary, Colaïtis, A., additional, and Batani, D., additional

Published

2022

38. Influence of the magnetic field on properties of hot electron emission from ablative plasma produced at laser irradiation of a disc-coil target

Author

Pisarczyk, T, primary, Renner, O, additional, Dudzak, R, additional, Chodukowski, T, additional, Rusiniak, Z, additional, Domanski, J, additional, Badziak, J, additional, Dostal, J, additional, Krupka, M, additional, Singh, S, additional, Klir, D, additional, Ehret, M, additional, Gajdos, P, additional, Zaras-Szydłowska, A, additional, Rosinski, M, additional, Tchórz, P, additional, Szymanski, M, additional, Krasa, J, additional, Burian, T, additional, Pfeifer, M, additional, Cikhardt, J, additional, Jelinek, S, additional, Kocourkova, G, additional, Batani, D, additional, Batani, K, additional, Santos, J, additional, Vlachos, C, additional, Ospina-Bohórquez, V, additional, Volpe, L, additional, Borodziuk, S, additional, Krus, M, additional, and Juha, L, additional

Published

2022

39. Cylindrical implosion platform for the study of highly magnetized plasmas at Laser MegaJoule

Author

Pérez-Callejo, G., primary, Vlachos, C., additional, Walsh, C. A., additional, Florido, R., additional, Bailly-Grandvaux, M., additional, Vaisseau, X., additional, Suzuki-Vidal, F., additional, McGuffey, C., additional, Beg, F. N., additional, Bradford, P., additional, Ospina-Bohórquez, V., additional, Batani, D., additional, Raffestin, D., additional, Colaïtis, A., additional, Tikhonchuk, V., additional, Casner, A., additional, Koenig, M., additional, Albertazzi, B., additional, Fedosejevs, R., additional, Woolsey, N., additional, Ehret, M., additional, Debayle, A., additional, Loiseau, P., additional, Calisti, A., additional, Ferri, S., additional, Honrubia, J., additional, Kingham, R., additional, Mancini, R. C., additional, Gigosos, M. A., additional, and Santos, J. J., additional

Published

2022

40. Reflecting laser-driven shocks in diamond in the megabar pressure range

Author

Jakubowska, K, Mancelli, D, Benocci, R, Trela, J, Errea, I, Martynenko, A, Neumayer, P, Rosmej, O, Borm, B, Molineri, A, Verona, C, Cannatà, D, Aliverdiev, A, Roman, H, Batani, D, Jakubowska, K., Mancelli, D., Benocci, R., Trela, J., Errea, I., Martynenko, A. S., Neumayer, P., Rosmej, O., Borm, B., Molineri, A., Verona, C., Cannatà, D., Aliverdiev, A., Roman, H. E., Batani, D., Jakubowska, K, Mancelli, D, Benocci, R, Trela, J, Errea, I, Martynenko, A, Neumayer, P, Rosmej, O, Borm, B, Molineri, A, Verona, C, Cannatà, D, Aliverdiev, A, Roman, H, Batani, D, Jakubowska, K., Mancelli, D., Benocci, R., Trela, J., Errea, I., Martynenko, A. S., Neumayer, P., Rosmej, O., Borm, B., Molineri, A., Verona, C., Cannatà, D., Aliverdiev, A., Roman, H. E., and Batani, D.

Abstract

In this work we present experimental results on the behavior of diamond at megabar pressure. The experiment was performed using the PHELIX facility at GSI in Germany to launch a planar shock into solid multi-layered diamond samples. The target design allows shock velocity in diamond and in two metal layers to be measured as well as the free surface velocity after shock breakout. As diagnostics, we used two velocity interferometry systems for any reflector (VISARs). Our measurements show that for the pressures obtained in diamond (between 3 and 9 Mbar), the propagation of the shock induces a reflecting state of the material. Finally, the experimental results are compared with hydrodynamical simulations in which we used different equations of state, showing compatibility with dedicated SESAME tables for diamond.

Published

2021

41. Application of harmonics imaging to focal spot measurements of the "PETAL" laser.

Author

Raffestin, D., Boutoux, G., Blanchot, N., Batani, D., D'Humières, E., Moreno, Q., Longhi, T., Coïc, H., Granet, F., Rault, J., Liberatore, C., Jakubowska, K., and Tikhonchuk, V.

Subjects

LASERS, IMAGING systems, COMPUTER simulation

Abstract

By using numerical simulations and experimental campaigns on a small-scale laser facility, the concept of the focal spot imaging on harmonics of laser frequency is developed and implemented on the Laser MegaJoule (LMJ)/PETawatt Aquitaine Laser (PETAL) facility. The Two/Three ω Imaging System was activated and validated during the first 2017–2019 interaction campaigns of PETAL on the LMJ. It provides major information on focal spot characteristics on a target. Such an approach could be easily applied to any high-intensity facility in the relativistic intensity regime (>1018 W cm−2). [ABSTRACT FROM AUTHOR]

Published

2019

42. Laser Ablation and Laser Induced Plasmas for Nanomachining and Material Analysis

Author

Batani, D., Vaseashta, A., editor, and Mihailescu, I. N., editor

Published

2008

43. Density Measurements of Shock Compressed Matter Using Short Pulse Laser Diagnostics

Author

Koenig, M., Ravasio, A., Benuzzi-Mounaix, A., Loupias, B., Ozaki, N., Borghesi, M., Cecchetti, C., Batani, D., Dezulian, R., Lepape, S., Patel, P., Park, H. S., Hicks, D., Mckinnon, A., Boehly, T., Schiavi, A., Henry, E., Notley, M., Clark, R., Bandyopadhyay, S., and Lebedev, Sergey V., editor

Published

2007

44. Radiative Shock Experiments at LULI

Author

Koenig, M., Vinci, T., Benuzzi-Mounaix, A., Lepape, S., Ozaki, N., Bouquet, S., Boireau, L., Leygnac, S., Michaut, C., Stehle, C., Chièze, J.-P., Batani, D., Hall, T., Tanaka, K., Yoshida, M., and Kyrala, G.A., editor

Published

2005

45. Density and Temperature Measurements on Laser Generated Radiative Shocks

Author

Vinci, T., Kœnig, M., Benuzzi-Mounaix, A., Boireau, L., Bouquet, S., Leygnac, S., Michaut, C., Stehlé, C., Peyrusse, O., Batani, D., and Kyrala, G.A., editor

Published

2005

46. Development of an experimental platform for the investigation of laser–plasma interaction in conditions relevant to shock ignition regime

Author

Tamagawa, T., primary, Hironaka, Y., additional, Kawasaki, K., additional, Tanaka, D., additional, Idesaka, T., additional, Ozaki, N., additional, Kodama, R., additional, Takizawa, R., additional, Fujioka, S., additional, Yogo, A., additional, Batani, D., additional, Nicolai, Ph., additional, Cristoforetti, G., additional, Koester, P., additional, Gizzi, L. A., additional, and Shigemori, K., additional

Published

2022

47. Thermal Soft X-Rays Interaction with foam Layered Gold Targets

Author

Batani, D., Desai, T., Löwer, Th., Hall, T. A., Nazarov, W., Koenig, M., Benuzzi-Mounaix, A., Stott, Peter E., editor, Wootton, Alan, editor, Gorini, Giuseppe, editor, Sindoni, Elio, editor, and Batani, Dimitri, editor

Published

2002

48. Study of Fast Electron Propagation in Ultra-Intense Laser Pulse Interaction with Solid Targets Using Rear Side Optical Self-Radiation and Reflectivity-Based Diagnostics

Author

Santos, J. J., Martinolli, E., Amiranoff, F., Batani, D., Baton, S. D., Bernardinello, A., Greison, G., Gremillet, L., Hall, T., Koenig, M., Pisani, F., Rabec Le Gloahec, M., Rousseaux, C., Batani, Dimitri, editor, Joachain, Charles J., editor, Martellucci, Sergio, editor, and Chester, Arthur N., editor

Published

2001

49. Equation of State of Water in the Megabar Range

Author

Henry, E., Batani, D., Koenig, M., Benuzzi, A., Masclet, I., Marchet, B., Rebec, M., Reverdin, Ch., Celliers, P., Da Silva, L., Cauble, R., Collins, G., Hall, T., Cavazzoni, C., Batani, Dimitri, editor, Joachain, Charles J., editor, Martellucci, Sergio, editor, and Chester, Arthur N., editor

Published

2001

50. Surface modification of copper using high intensity, 1015 W/cm2, femtosecond laser in vacuum

Author

Momcilovic, M., Limpouch, J., Kmetik, V., Redaelli, R., Savovic, J., Batani, D., Stasic, J., Panjan, P., and Trtica, M.

Published

2012