Your search keyword '"Pikuz, T."' showing total 274 results

1. Demonstration of The Brightest Nano-size Gamma Source

Author

Pirozhkov, A. S., Sagisaka, A., Ogura, K., Vishnyakov, E. A., Shatokhin, A. N., Armstrong, C. D., Esirkepov, T. Zh., Izquierdo, B. Gonzalez, Pikuz, T. A., Hadjisolomou, P., Alkhimova, M. A., Arran, C., Tsygvintsev, I. P., Valenta, P., Pikuz, S. A., Yan, W., Jeong, T. M., Singh, S., Finke, O., Grittani, G., Nevrkla, M., Lazzarini, C., Velyhan, A., Hayakawa, T., Fukuda, Y., Koga, J. K., Ishino, M., Kondo, Ko., Miyasaka, Y., Kon, A., Nishikino, M., Nosach, Y. V., Khikhlukha, D., Kolesnikov, A. O., Ragozin, E. N., Gasilov, V. A., Kumar, D., Nejdl, J., Sasorov, P. V., Weber, S., Margarone, D., Kato, Y., Korn, G., Kiriyama, H., Kondo, K., Ridgers, C., Kawachi, T., Kando, M., and Bulanov, S. V.

Subjects

Physics - Plasma Physics, Astrophysics - High Energy Astrophysical Phenomena, Physics - Optics

Abstract

Gamma rays consist of high-energy photons that selectively interact with nuclei, induce and mediate nuclear reactions and elementary particle interactions, and exceed x-rays in penetrating power and thus are indispensable for analysis and modification of dense or compressed object interior. Yet, the available gamma sources lack power and brightness which, if available, would revolutionize science and technology. The predicted laser-driven Gamma Flash (GF) would be the highest-power and the brightest terrestrial gamma source with a 30-40% laser-to-gamma energy conversion. It is based on inverse Compton scattering in a laser-solid interaction at irradiance typically above $10^{23}W/cm^2$. GF is one of the motivating goals for the most advanced laser facilities. However, till now GF remains overshadowed by simultaneously generated low-brightness Bremsstrahlung. Here we experimentally differentiate these two mechanisms and demonstrate a GF dominant regime producing several times the number of Bremsstrahlung photons. We found steep GF yield growth with the laser power and irradiance. Simulations revealed a Terawatt GF with nanometre source and an attosecond pulse train with a record brightness of $~10^{22}photons/mm^2mrad^2s0.1\%BW$ at up to tens of MeV. The small source size and high brightness paves the way towards spatially coherent gamma rays. At high photon energies, our regime is comparable in brightness to astrophysical Gamma Ray Bursts. We anticipate that the gamma ray source based on our findings will facilitate a breakthrough in research on future inertial fusion energy by enabling high-spatial-resolution time-resolved radiography of fuel mixing instabilities in extremely compressed targets. Such a new compact bright ultrafast gamma source could facilitate significant advances in time-resolved nuclear physics, homeland security, and nuclear waste management and non-proliferation., Comment: 36 pages, 11 figures

Published

2024

2. Laser-Driven Proton-Only Acceleration in a Multicomponent Near-Critical-Density Plasma

Author

Sakawa, Y., Ishihara, H., Ryazantsev, S. N., Alkhimova, M. A., Kumar, R., Kuramoto, O., Matsumoto, Y., Ota, M., Egashira, S., Nakagawa, Y., Minami, T., Sakai, K., Taguchi, T., Habara, H., Kuramitsu, Y., Morace, A., Abe, Y., Arikawa, Y., Fujioka, S., Kanasaki, M., Asai, T., Morita, T., Fukuda, Y., Pikuz, S., Pikuz, T., Ohira, Y., Doehl, L. N. K., Woolsey, N., and Sano, T.

Subjects

Physics - Plasma Physics, Astrophysics - High Energy Astrophysical Phenomena

Abstract

An experimental investigation of collisionless shock ion acceleration is presented using a multicomponent plasma and a high-intensity picosecond duration laser pulse. Protons are the only accelerated ions when a near-critical-density plasma is driven by a laser with a modest normalized vector potential. The results of particle-in-cell simulations imply that collisionless shock may accelerate protons alone selectively, which can be an important tool for understanding the physics of inaccessible collisionless shocks in space and astrophysical plasma.

Published

2024

3. High-order alloharmonics produced by nonperiodic drivers

Author

Pirozhkova, M. S., Ogura, K., Sagisaka, A., Esirkepov, T. Zh., Faenov, A. Ya., Pikuz, T. A., Kotaki, H., Hayashi, Y., Fukuda, Y., Koga, J. K., Bulanov, S. V., Daido, H., Hasegawa, N., Ishino, M., Nishikino, M., Koike, M., Kawachi, T., Kiriyama, H., Kando, M., Neely, D., and Pirozhkov, A. S.

Subjects

Physics - Classical Physics, General Relativity and Quantum Cosmology, Physics - Optics

Abstract

High-order harmonics are ubiquitous in nature and present in electromagnetic, acoustic, and gravitational waves. They are generated by periodic nonlinear processes or periodic high-frequency pulses. However, this periodicity is often inexact, such as that in chirped (frequency-swept) optical waveforms or interactions with nonstationary matter -- for instance, reflection from accelerating mirrors. Spectra observed in such cases contain complicated sets of harmonic-like fringes. We encountered such fringes in our experiment on coherent extreme ultraviolet generation via BISER, and could not interpret them using currently available knowledge. Here, we present a comprehensive theory based on interference of harmonics with different orders fully explaining the formation of these fringes, which we call alloharmonics. Like atomic spectra, the complex alloharmonic spectra depend on several integer numbers and bear a unique imprint of the emission process, which the theory can decipher, avoiding confusion or misinterpretation. We also demonstrate the alloharmonics in simulations of gravitational waves emitted by binary black hole mergers. Further, we predict the presence of alloharmonics in the radio spectra of pulsars and in optical frequency combs, and propose their use for measurement of extremely small accelerations necessary for testing gravity theories. The alloharmonics phenomenon generalizes classical harmonics and is critical in research fields such as laser mode locking, frequency comb generation, attosecond pulse generation, pulsar studies, and future gravitational wave spectroscopy., Comment: 29 pages, 9 figures, 3 tables

Published

2023

4. Direct imaging of shock wave splitting in diamond at Mbar pressures

Author

Makarov, S. S., Dyachkov, S. A., Pikuz, T. A., Katagiri, K., Zhakhovsky, V. V., Inogamov, N. A., Khokhlov, V. A., Martynenko, A. S., Albertazzi, B., Rigon, G., Mabey, P., Hartley, N., Inubushi, Y., Miyanishi, K., Sueda, K., Togashi, T., Yabashi, M., Yabuuchi, T., Kodama, R., Pikuz, S. A., Koenig, M., and Ozaki, N.

Subjects

Physics - Plasma Physics, Condensed Matter - Materials Science

Abstract

The propagation of a shock wave in solids can stress them to ultra-high pressures of millions of atmospheres. Understanding the behavior of matter at these extreme pressures is essential to describe a wide range of physical phenomena, including the formation of planets, young stars and cores of super-Earths, as well as the behavior of advanced ceramic materials subjected to such stresses. Under megabar (Mbar) pressure, even a solid with high strength exhibits plastic properties, causing the shock wave to split in two. This phenomenon is described by theoretical models, but without direct experimental measurements to confirm them, their validity is still in doubt. Here, we present the results of an experiment in which the evolution of the coupled elastic-plastic wave structure in diamond was directly observed and studied with submicron spatial resolution, using the unique capabilities of the X-ray free-electron laser. The direct measurements allowed, for the first time, the fitting and validation of a strength model for diamond in the range of several Mbar by performing continuum mechanics simulations in 2D geometry. The presented experimental approach to the study of shock waves in solids opens up new possibilities for the direct verification and construction of the equations of state of matter in the ultra-high pressure range, which are relevant for the solution of a variety of problems in high energy density physics., Comment: 14 pages, 15 figures, submitted to Nature

Published

2022

5. Using Diffuse Scattering to Observe X-Ray-Driven Nonthermal Melting

Author

Hartley, N. J., Grenzer, J., Huang, L., Inubushi, Y., Kamimura, N., Katagiri, K., Kodama, R., Kon, A., Lu, W., Makita, M., Matsuoka, T., Nakajima, S., Ozaki, N., Pikuz, T., Rode, A., Sagae, D., Schuster, A. K., Tono, K., Voigt, K., Vorberger, J., Yabuuchi, T., McBride, E. E., and Kraus, D.

Subjects

Physics - Plasma Physics

Abstract

We present results from the SPring-8 Angstrom Compact free electron LAser (SACLA) XFEL facility, using a high intensity ($\sim\!10^{20}\,$W/cm$^2$) X-ray pump X-ray probe scheme to observe changes in the ionic structure of silicon induced by X-ray heating of the electrons. By avoiding Laue spots in the scattering signal from a single crystalline sample, we observe a rapid rise in diffuse scattering, which we attribute to a loss of lattice order and a transition to a liquid state within 100 fs of irradiation, a timescale which agrees well with first principles simulations, but is faster than that predicted by purely inertial behavior. This method is capable of observing liquid scattering without masking or filtering of signal from the ambient solid, allowing the liquid structure to be measured throughout and beyond the phase change., Comment: 6 pages, 5 figures. Updated title and abstract

Published

2020

6. All femtosecond optical pump and X-ray probe: holey-axicon for free electron laser

Author

Anand, V., Maksimovic, J., Katkus, T., Ng, S. H., Ulcinas, O., Mikutis, M., Baltrukonis, J., Urbas, A., Slekys, G., Ogura, H., Sagae, D., Pikuz, T., Somekawa, T., Ozaki, N., Vailionis, A., Seniutinas, G., Mizeikis, V., Glazebrook, K., Brodie, J. P., Stoddart, P. R., Rapp, L., Rode, A. V., Gamaly, E. G., and Juodkazis, S.

Subjects

Physics - Optics, High Energy Physics - Experiment

Abstract

We put forward a co-axial pump(optical)-probe(X-rays) experimental concept and show performance of the optical component. A Bessel beam generator with a central 100 micrometers-diameter hole (on the optical axis) was fabricated using femtosecond (fs) laser structuring inside a silica plate. This flat-axicon optical element produces a needle-like axial intensity distribution which can be used for the optical pump pulse. The fs-X-ray free electron laser (X-FEL) beam of sub-1 micrometer diameter can be introduced through the central hole along the optical axis onto a target as a probe. Different realisations of optical pump are discussed. Such optical elements facilitate alignment of ultra-short fs-pulses in space and time and can be used in light-matter interaction experiments at extreme energy densities on the surface and in the volume of targets. Full advantage of ultra-short 10 fs X-FEL probe pulses with fs-pump(optical) opens an unexplored temporal dimension of phase transitions and the fastest laser-induced rates of material heating and quenching. A wider field of applications of fs-laser-enabled structuring of materials and design of specific optical elements for astrophotonics is presented.

Published

2020

7. In-vacuum post-compression of optical probe pulse for relativistic plasma diagnostics

Author

Lorenz, S., primary, Grittani, G. M., additional, Kondo, K., additional, Kon, A., additional, Liu, Y.-K., additional, Sagisaka, A., additional, Ogura, K., additional, Nakanii, N., additional, Huang, K., additional, Bierwage, A., additional, Namba, S., additional, Ohiro, H., additional, Pikuz, T. A., additional, Koga, J. K., additional, Chen, P., additional, Kiriyama, H., additional, Kando, M., additional, Esirkepov, T. Zh., additional, Bulanov, S. V., additional, and Pirozhkov, A. S., additional

Published

2024

8. Optimization of laser-driven quantum beam generation and the applications with artificial intelligence

Author

Kuramitsu, Y., primary, Taguchi, T., additional, Nikaido, F., additional, Minami, T., additional, Hihara, T., additional, Suzuki, S., additional, Oda, K., additional, Kuramoto, K., additional, Yasui, T., additional, Abe, Y., additional, Ibano, K., additional, Takabe, H., additional, Chu, C. M., additional, Wu, K. T., additional, Woon, W. Y., additional, Chen, S. H., additional, Jao, C. S., additional, Chen, Y. C., additional, Liu, Y. L., additional, Morace, A., additional, Yogo, A., additional, Arikawa, Y., additional, Kohri, H., additional, Tokiyasu, A., additional, Kodaira, S., additional, Kusumoto, T., additional, Kanasaki, M., additional, Asai, T., additional, Fukuda, Y., additional, Kondo, K., additional, Kiriyama, H., additional, Hayakawa, T., additional, Tanaka, S. J., additional, Isayama, S., additional, Watamura, N., additional, Suzuki, H., additional, Kumar, H. S., additional, Ohnishi, N., additional, Pikuz, T., additional, Filippov, E., additional, Sakai, K., additional, Yasuhara, R., additional, Nakata, M., additional, Ishikawa, R., additional, Hoshi, T., additional, Mizuta, A., additional, Bolouki, N., additional, Saura, N., additional, Benkadda, S., additional, Koenig, M., additional, and Hamaguchi, S., additional

Published

2024

9. Generation of Short Wavelength Radiation and Energetic Particles by Using PW-Class Lasers

Author

Kawachi, T., Nishikino, M., Sasaki, A., Hasegawa, N., Ishino, M., Dinh, T.-H., Mikami, K., Kitamura, T., Kiriyama, H., Pirozhkov, A. S., Esirkepov, T. Th., Sagisaka, A., Nishiuchi, M., Sakaki, H., Kando, M., Faenov, A. Ya., Pikuz, T. A., Kawase, K., Nagai, R., Hajima, R., Bulanov, S. V., Kondo, K., Kozlová, Michaela, editor, and Nejdl, Jaroslav, editor

Published

2020

10. Burst intensification by singularity emitting radiation in multi-stream flows

Author

Pirozhkov, A. S., Esirkepov, T. Zh., Pikuz, T. A., Faenov, A. Ya., Ogura, K., Hayashi, Y., Kotaki, H., Ragozin, E. N., Neely, D., Kiriyama, H., Koga, J. K., Fukuda, Y., Sagisaka, A., Nishikino, M., Imazono, T., Hasegawa, N., Kawachi, T., Bolton, P. R., Daido, H., Kato, Y., Kondo, K., Bulanov, S. V., and Kando, M.

Subjects

Physics - Plasma Physics

Abstract

In various media the elementary components can emit traveling waves such as electromagnetic, gravitational or acoustic types. If these elementary emitters are synchronized, the resulting emission is coherent. Moreover, the faster the emitters approach an observer, the more intense and directional their apparent emission is, with associated frequency increase. Multi-stream flows ubiquitously occur in media (such as with shock waves and jets in astrophysical and laboratory plasmas) and produce fast moving density singularities, where high concentration and synchronism can bring constructive interference. However, a singularity emitting such characteristic coherent radiation has not been demonstrated yet. We show this general phenomenon in laser-driven relativistic plasma, which is an ideal medium for realizing these effects in the laboratory under controllable conditions. Our experiments and simulations reveal bright coherent soft x-ray radiation from nanoscale electron density singularities in multi-stream plasma. They constitute a new compact x-ray source of ultrashort duration, demanded in numerous applications. In general, singularities can be bright sources of other types of traveling waves. Thus our findings open new opportunities in different fields of science. For example, gravitational wave generation, as proposed in ultrahigh-energy accelerators, can be significantly enhanced by intentionally induced density singularities in the particle bunches. Further, we anticipate that multi-stream flows in cosmic media can produce intense bursts of coherent electromagnetic and/or gravitational waves, especially at longer wavelengths which facilitate constructive interference. We can then expect to observe more directional short wavelength bursts from cosmic emitters approaching at relativistic speeds. Thus, we present a new framework for interpreting a broad range of experimental results.

Published

2016

11. Advanced spectroscopic investigation of colour centres in LiF crystals irradiated with monochromatic hard x-rays

Author

Vincenti, M A, primary, Montereali, R M, additional, Bonfigli, F, additional, Nichelatti, E, additional, Nigro, V, additional, Piccinini, M, additional, Koenig, M, additional, Mabey, P, additional, Rigon, G, additional, Dabrowski, H J, additional, Benkadoum, Y, additional, Mercere, P, additional, Da Silva, P, additional, Pikuz, T, additional, Ozaki, N, additional, Makarov, S, additional, Pikuz, S, additional, and Albertazzi, B, additional

Published

2024

12. Micron-scale phenomena observed in a turbulent laser-produced plasma

Author

Rigon, G., Albertazzi, B., Pikuz, T., Mabey, P., Bouffetier, V., Ozaki, N., Vinci, T., Barbato, F., Falize, E., Inubushi, Y., Kamimura, N., Katagiri, K., Makarov, S., Manuel, M. J.-E., Miyanishi, K., Pikuz, S., Poujade, O., Sueda, K., Togashi, T., Umeda, Y., Yabashi, M., Yabuuchi, T., Gregori, G., Kodama, R., Casner, A., and Koenig, M.

Published

2021

13. Study of the Parameters of a High-Intensity Thermal and Coherent X-ray Sources with the Use of LiF Crystal Detector (Review)

Author

Makarov, S. S., Zhvania, I. A., Pikuz, S. A., Pikuz, T. A., and Skobelev, I. Yu.

Published

2020

14. Ultra-intense X-Ray Radiation Photopumping of Exotic States of Matter by Relativistic Laser–Plasma in the Radiation-Dominated Kinetic Regime (RDKR)

Author

Faenov, A. Ya., Colgan, J., Pikuz, S. A., Zhidkov, A., Pikuz, T. A., Abdallah, J., Jr., Tubman, E., Butler, N. M. H., Dance, R. J., Skobelev, I. Yu., Alkhimova, M. Z., Booth, N., Green, J., Gregory, C., Andreev, A., Nishiuchi, M., Sakaki, H., Sagisaka, A., Pirozhkov, A. S., Ogura, K., Fukuda, Y., Kanasaki, M., Hasegawa, N., Nishikino, M., Kando, M., Kawachi, T., Kondo, K., McKenna, P., Tallents, G. J., Woolsey, N., Kodama, R., Kawachi, Tetsuya, editor, Bulanov, Sergei V., editor, Daido, Hiroyuki, editor, and Kato, Yoshiaki, editor

Published

2018

15. Research on Laser Acceleration and Coherent X-Ray Generation Using J-KAREN-P Laser

Author

Kando, M., Pirozhkov, A. S., Nishiuchi, M., Kiriyama, H., Kon, A., Sakaki, H., Fukuda, Y., Dover, N., Sekiguchi, K., Nishitani, K., Sagisaka, A., Pikuz, T. A., Faenov, A. Ya., Ogura, K., Hayashi, Y., Kotaki, H., Esirkepov, T. Zh., Huang, K., Nakanii, N., Kondo, K., Koga, J. K., Bulanov, S. V., Kawachi, Tetsuya, editor, Bulanov, Sergei V., editor, Daido, Hiroyuki, editor, and Kato, Yoshiaki, editor

Published

2018

16. High-Order Harmonic Generation by Relativistic Plasma Singularities: The Driving Laser Requirements

Author

Pirozhkov, A. S., Esirkepov, T. Zh., Pikuz, T. A., Faenov, A. Ya., Ogura, K., Hayashi, Y., Kotaki, H., Ragozin, E. N., Neely, D., Kiriyama, H., Koga, J. K., Fukuda, Y., Sagisaka, A., Nishikino, M., Imazono, T., Hasegawa, N., Kawachi, T., Daido, H., Kato, Y., Bulanov, S. V., Kondo, K., Kando, M., Kawachi, Tetsuya, editor, Bulanov, Sergei V., editor, Daido, Hiroyuki, editor, and Kato, Yoshiaki, editor

Published

2018

17. In Situ Characterization of XFEL Beam Intensity Distribution and Focusability by High-Resolution LiF Crystal Detector

Author

Pikuz, T. A., Faenov, A. Ya., Matsuoka, T., Albertazzi, B., Ozaki, N., Hartely, N., Muray Ricardo Arturo, O., Yabuuchi, T., Habara, H., Matsuyama, S., Yamauchi, K., Inubushi, Y., Togashi, T., Yumoto, H., Tange, Y., Tono, K., Sato, Y., Yabashi, M., Nishikino, M., Kawachi, T., Mitrofanov, A., Pikuz, S. A., Bleiner, D., Grum-Grzhimailo, A., Rosanov, N. N., Vysotina, N. V., Harmand, M., Koenig, M., Tanaka, K. A., Ishikawa, T., Kodama, R., Kawachi, Tetsuya, editor, Bulanov, Sergei V., editor, Daido, Hiroyuki, editor, and Kato, Yoshiaki, editor

Published

2018

18. Progress and Prospects of X-Ray Laser Research in QST

Author

Nishikino, M., Hasegawa, N., Ishino, M., Imazono, T., Sasaki, A., Mikami, K., Dinh, T. -H., Suemoto, T., Namba, S., Faenov, A. Ya., Pikuz, T. A., Ichimaru, S., Hatayama, M., Kawachi, T., Kawachi, Tetsuya, editor, Bulanov, Sergei V., editor, Daido, Hiroyuki, editor, and Kato, Yoshiaki, editor

Published

2018

19. Ultrafast anisotropic disordering in graphite driven by intense hard X-ray pulses

Author

Hartley, N.J., Grenzer, J., Lu, W., Huang, L.G., Inubushi, Y., Kamimura, N., Katagiri, K., Kodama, R., Kon, A., Lipp, V., Makita, M., Matsuoka, T., Medvedev, N., Nakajima, S., Ozaki, N., Pikuz, T., Rode, A.V., Rohatsch, K., Sagae, D., Schuster, A.K., Tono, K., Vorberger, J., Yabuuchi, T., and Kraus, D.

Published

2019

20. Study of Optical Emission During Spallative Ablation Induced by Soft X-Ray Laser Pulses

Author

Ishino, M., Nishikino, M., Hasegawa, N., Pikuz, T., Skobelev, I., Faenov, A., Yamagiwa, M., Kawachi, T., Rocca, Jorge, editor, Menoni, Carmen, editor, and Marconi, Mario, editor

Published

2016

21. Progress and Prospects of Coherent X-Ray Research Using High Power Lasers in Japan Atomic Energy Agency

Author

Kawachi, T., Nishikino, M., Sasaki, A., Ishino, M., Hasegawa, N., Imazono, T., Pikuz, T. A., Faenov, A. Y., Magnitskiy, M., Maruyama, M., Tomita, T., Suemoto, T., Pirozhkov, A. S., Bulanov, S. V., Kiriyama, H., Kando, M., Yamagiwa, M., Kondo, K., Bolton, P., Kato, Y., Rocca, Jorge, editor, Menoni, Carmen, editor, and Marconi, Mario, editor

Published

2016

22. Optical characterization of lithium fluoride thin-film imaging detectors for monochromatic hard X-rays

Author

Vincenti, M.A., primary, Montereali, R.M., additional, Nichelatti, E., additional, Nigro, V., additional, Piccinini, M., additional, Koenig, M., additional, Mabey, P., additional, Rigon, G., additional, Dabrowski, H.J., additional, Benkadoum, Y., additional, Mercere, P., additional, Da Silva, P., additional, Pikuz, T., additional, Ozaki, N., additional, Makarov, S., additional, Pikuz, S., additional, and Albertazzi, B., additional

Published

2023

23. Corrigendum to ultrafast anisotropic disordering in graphite driven by intense hard X-ray pulses

Author

Hartley, N.J., primary, Grenzer, J., additional, Lu, W., additional, Huang, L.G., additional, Inubushi, Y., additional, Kamimura, N., additional, Katagiri, K., additional, Kodama, R., additional, Kon, A., additional, Lipp, V., additional, Makita, M., additional, Matsuoka, T., additional, Medvedev, N., additional, Nakajima, S., additional, Ozaki, N., additional, Pikuz, T., additional, Rode, A.V., additional, Sagae, D., additional, Schuster, A.K., additional, Tono, K., additional, Voigt, K., additional, Vorberger, J., additional, Yabuuchi, T., additional, and Kraus, D., additional

Published

2023

24. Direct LiF imaging diagnostics on refractive X-ray focusing at the EuXFEL High Energy Density instrument

Author

Makarov, S, Makita, M, Nakatsutsumi, M, Pikuz, T, Ozaki, N, Preston, T, Appel, K, Konopkova, Z, Cerantola, V, Brambrink, E, Schwinkendorf, J, Mohacsi, I, Burian, T, Chalupsky, J, Hajkova, V, Juha, L, Vozda, V, Nagler, B, Zastrau, U, Pikuz, S, Makarov, Sergey, Makita, Mikako, Nakatsutsumi, Motoaki, Pikuz, Tatiana, Ozaki, Norimasa, Preston, Thomas R., Appel, Karen, Konopkova, Zuzana, Cerantola, Valerio, Brambrink, Erik, Schwinkendorf, Jan-Patrick, Mohacsi, Istvan, Burian, Tomas, Chalupsky, Jaromir, Hajkova, Vera, Juha, Libor, Vozda, Vojtech, Nagler, Bob, Zastrau, Ulf, Pikuz, Sergey, Makarov, S, Makita, M, Nakatsutsumi, M, Pikuz, T, Ozaki, N, Preston, T, Appel, K, Konopkova, Z, Cerantola, V, Brambrink, E, Schwinkendorf, J, Mohacsi, I, Burian, T, Chalupsky, J, Hajkova, V, Juha, L, Vozda, V, Nagler, B, Zastrau, U, Pikuz, S, Makarov, Sergey, Makita, Mikako, Nakatsutsumi, Motoaki, Pikuz, Tatiana, Ozaki, Norimasa, Preston, Thomas R., Appel, Karen, Konopkova, Zuzana, Cerantola, Valerio, Brambrink, Erik, Schwinkendorf, Jan-Patrick, Mohacsi, Istvan, Burian, Tomas, Chalupsky, Jaromir, Hajkova, Vera, Juha, Libor, Vozda, Vojtech, Nagler, Bob, Zastrau, Ulf, and Pikuz, Sergey

Abstract

The application of fluorescent crystal media in wide-range X-ray detectors provides an opportunity to directly image the spatial distribution of ultra-intense X-ray beams including investigation of the focal spot of free-electron lasers. Here the capabilities of the micro- and nano-focusing X-ray refractive optics available at the High Energy Density instrument of the European XFEL are reported, as measured in situ by means of a LiF fluorescent detector placed into and around the beam caustic. The intensity distribution of the beam focused down to several hundred nanometers was imaged at 9 keV photon energy. A deviation from the parabolic surface in a stack of nanofocusing Be compound refractive lenses (CRLs) was found to affect the resulting intensity distribution within the beam. Comparison of experimental patterns in the far field with patterns calculated for different CRL lens imperfections allowed the overall inhomogeneity in the CRL stack to be estimated. The precise determination of the focal spot size and shape on a sub-micrometer level is essential for a number of high energy density studies requiring either a pin-size backlighting spot or extreme intensities for X-ray heating.

Published

2023

25. Plasma diagnostics from intensities of resonance line series of He-like ions

Author

Ryazantsev, S. N., Skobelev, I. Yu., Faenov, A. Ya., Grum-Grzhimailo, A. N., Pikuz, T. A., and Pikuz, S. A.

Published

2017

26. Formation of a plasma with the determining role of radiative processes in thin foils irradiated by a pulse of the PEARL subpetawatt laser

Author

Pikuz, S. A., Skobelev, I. Yu., Alkhimova, M. A., Pokrovskii, G. V., Colgan, J., Pikuz, T. A., Faenov, A. Ya., Soloviev, A. A., Burdonov, K. F., Eremeev, A. A., Sladko, A. D., Osmanov, R. R., Starodubtsev, M. V., Ginzburg, V. N., Kuz’min, A. A., Sergeev, A. M., Fuchs, J., Khazanov, E. A., Shaikin, A. A., Shaikin, I. A., and Yakovlev, I. V.

Published

2017

27. Advanced high resolution x-ray diagnostic for HEDP experiments

Author

Faenov, A. Y., Pikuz, T. A., Mabey, P., Albertazzi, B., Michel, Th., Rigon, G., Pikuz, S. A., Buzmakov, A., Makarov, S., Ozaki, N., Matsuoka, T., Katagiri, K., Miyanishi, K., Takahashi, K., Tanaka, K. A., Inubushi, Y., Togashi, T., Yabuuchi, T., Yabashi, M., Casner, A., Kodama, R., and Koenig, M.

Published

2018

28. Ion energy spectra directly measured in the interaction volume of intense laser pulses with clustered plasma

Author

Bochkarev, S. G., Faenov, A., Pikuz, T., Brantov, A. V., Kovalev, V. F., Skobelev, I., Pikuz, S., Kodama, R., Popov, K. I., and Bychenkov, V. Yu.

Published

2018

29. Towards a novel laser-driven method of exotic nuclei extraction−acceleration for fundamental physics and technology

Author

Nishiuchi, M., Sakaki, H., Esirkepov, T. Zh., Nishio, K., Pikuz, T. A., Faenov, A. Ya., Skobelev, I. Yu., Orlandi, R., Pirozhkov, A. S., Sagisaka, A., Ogura, K., Kanasaki, M., Kiriyama, H., Fukuda, Y., Koura, H., Kando, M., Yamauchi, T., Watanabe, Y., Bulanov, S. V., Kondo, K., Imai, K., and Nagamiya, S.

Published

2016

30. The Spectr-W3 database on the spectroscopic properties of atoms and ions

Author

Skobelev, I. Yu., Loboda, P. A., Gagarin, S. V., Ivliev, S. V., Kozlov, A. I., Morozov, S. V., Pikuz, Jr., S. A., Pikuz, T. A., Popova, V. V., and Faenov, A. Ya.

Published

2016

31. X-ray spectroscopy diagnostics of a recombining plasma in laboratory astrophysics studies

Author

Ryazantsev, S. N., Skobelev, I. Yu., Faenov, A. Ya., Pikuz, T. A., Grum-Grzhimailo, A. N., and Pikuz, S. A.

Published

2015

32. Hydrodynamic instabilities in a highly radiative environment

Author

Rigon, G., primary, Albertazzi, B., additional, Mabey, P., additional, Michel, Th., additional, Barroso, P., additional, Faenov, A., additional, Kumar, R., additional, Michaut, C., additional, Pikuz, T., additional, Sakawa, Y., additional, Sano, T., additional, Shimogawara, H., additional, Tamatani, S., additional, Casner, A., additional, and Koenig, M., additional

Published

2022

33. Optimization of BISER via Laser and Plasma Tuning

Author

Shatokhin, A., Kotov, A., M. Jeong, T., M. Grittani, G., Dzelzainis, T., Hull, G., Dann, S., Akito, Sagisaka, Vishnyakov, E., Kolesnikov, A., Masato, Koike, Timur, Esirkepov, Masaki, Kando, Koichi, Ogura, A. Pikuz, T., Kevin Koga, James, Hiromitsu, Kiriyama, Soloviev, A., Ragozin, E., Bulanov, Sergey, Kiminori, Kondo, Tetsuya, Kawachi, Symes, D., Neely, D., and Pirozhkov, Alexander

Abstract

1. Introduction Burst Intensification by Singularity Emitting Radiation (BISER) [1] is the emission of coherent traveling waves by multi-stream flow singularities. Such singularities can be produced in relativistic plasma by high-power lasers, resulting in very bright coherent x-ray emission [2],[3]. 2. Experimental We have recently performed an experiment on BISER coherent x-ray generation with the Astra Laser at the CLF RAL, UK. We extensively optimized the experimental conditions, namely the plasma density and profile, and laser spot [4] and pulse, making use of substantial beam time. This resulted in a ~2 orders of magnitude higher BISER brightness compared to earlier experiments with 10 TW lasers. 3. Results In this presentation we discuss results from two soft x-ray spectrographs: a three-channel flat field spectrograph [5] in the forward direction (channels at −0.6, 0, and 0.8°) operating in the 17-34 nm range and a normal-incidence imaging spectrograph [6] in a 10° off-axis direction operating in the 12.4-20 nm range. Under optimum conditions, both spectrographs showed μJ and higher BISER pulse energies per shot in the corresponding spectral ranges and within their acceptance angles. This implies multi-100 μJ BISER pulses in the entire spectral range and within the full angular width. Acknowledgement We acknowledge support from the Astra Laser Group and the CLF Target Fab, Mechanical, and Electrical. Financial support: JSPS Kakenhi JP 19KK0355 and 19H00669, CLF, Russian Science Foundation (20-62-46050), IAP RAS, ELI-Beamlines, MŠMT by the project "Advanced Research Using High Intensity Laser Produced Photons and Particles" (CZ.02.1.01/0.0/0.0/16_019/0000789), High Field Initiative (CZ.02.1.01/0.0/0.0/15_003/0000449) from the European Regional Development Fund, and the QST Director Fund 創成的研究 #20. References [1]A. S. Pirozhkov, T. Zh. Esirkepov et al., "Burst intensification by singularity emitting radiation in multi-stream flows," Sci. Rep. 7, 17968 (2017). [2]A. S. Pirozhkov, et al. "Soft-X-Ray Harmonic Comb from Relativistic Electron Spikes" PRL 108, 135004 (2012). [3]A. S. Pirozhkov, et al., "High order harmonics from relativistic electron spikes" NJP 16, 093003 (2014). [4]A. S. Pirozhkov, et al. "Laser Requirements for High-Order Harmonic Generation by Relativistic Plasma Singularities," Quantum Beam Sci. 2, 7 (2018). [5]D. Neely, et al., "A multi-channel soft X-ray flat-field spectrometer," AIP Conf. Proc. 426, 479 (1998). [6]A. N. Shatokhin, et al., "High-resolution stigmatic spectrograph for a wavelength range of 12.5-30 nm," Opt. Express 26, 19009 (2018)., OPIC-2022 (ALPS-2022)

Published

2022

34. BISER enhancement with Astra laser

Author

Shatokhin, A., Kotov, A., M. Jeong, T., M. Grittani, G., Dzelzainis, T., Hull, G., Dann, S., Akito, Sagisaka, Vishnyakov, E., Kolesnikov, A., Masato, Koike, Timur, Esirkepov, Masaki, Kando, Koichi, Ogura, A. Pikuz, T., Kevin Koga, James, Hiromitsu, Kiriyama, Soloviev, A., Ragozin, E., Bulanov, Sergey, Kiminori, Kondo, Tetsuya, Kawachi, Symes, D., Neely, D., and Pirozhkov, Alexander

Abstract

Burst Intensification by Singularity Emitting Radiation (BISER) [1] is the phenomenon of extremely bright coherent wave emission (constructive interference, N^2 effect) by singularities of multi-stream flows. High-power femtosecond lasers can produce such flows and corresponding relativistic plasma singularities in underdense plasma; these singularities emit very bright coherent x-rays [2]-[3]. We have recently performed an experiment on BISER coherent x-ray generation with the Astra Laser in the CLF RAL, UK. We observed BISER coherent soft x-rays with two spectrographs: a three-channel flat field spectrograph [4] in the forward direction (channels at -0.6, 0, and 0.8°) operating in the 17-34 nm range and a normal-incidence imaging spectrograph [5] in a 10° off-axis direction operating in the 12.4-20 nm range. Both spectrographs, in addition, provided data on the angular distribution of the BISER radiation. We took advantage of an extensive experiment term and long daily laser operation hours to optimize the laser (in particular, focal spot, which is a necessary prerequisite for BISER [6], and pulse width) and the experimental conditions (in particular, the density profile). These resulted in ~2 orders of magnitude enhancement in BISER photon number, providing >10^11 photons and >μJ energies per pulse in each channel at 7 TW laser power, the result which could previously be obtained at >100 TW laser power only. We acknowledge support from the Astra Laser Group and the CLF Target Fab, Mechanical, and Electrical. Financial support: JSPS Kakenhi JP 19KK0355 and 19H00669, CLF, Russian Science Foundation (20-62-46050), IAP RAS, ELI-Beamlines, the Ministry of Education, Youth and Sports of the Czech Republic by the project "Advanced Research Using High Intensity Laser Produced Photons and Particles" (CZ.02.1.01/0.0/0.0/16_019/0000789), and the QST Director Fund 創成的研究 #20. [1] A. Pirozhkov, T. Esirkepov et al., "Burst intensification by singularity emitting radiation in multi-stream flows," Sci. Rep. 7, 17968 (2017). [2] A. S. Pirozhkov et al. "Soft-X-Ray Harmonic Comb from Relativistic Electron Spikes" PRL 108 135004 (2012) [3] A. S. Pirozhkov et al., "High order harmonics from relativistic electron spikes" New J. Phys. 16, 093003 (2014). [4] D. Neely et al., "A multi-channel soft X-ray flat-field spectrometer," AIP Conf. Proc. 426, 479 (1998). [5] A. Shatokhin et al., "High-resolution stigmatic spectrograph for a wavelength range of 12.5-30 nm," Opt. Express 26 19009 (2018). [6] A. S. Pirozhkov, et al. "Laser Requirements for High-Order Harmonic Generation by Relativistic Plasma Singularities," Quantum Beam Sci. 2, 7 (2018)., Annual meeting of the JSAP

Published

2022

35. Small Angle X-ray Scattering and particle measurements of sub-micron rod-assembly target at SACLA

Author

Sakawa, Youichi, Ota, M., Matsumoto, Y., Rodel, M., Pikuz, T., Pirozhkov, Alexander, Egashira, S., Takumi, Minami, Sakai, K., Ishihara, D., Kuramoto, O., Maeda, K., Abe, Y., Nakamura, H., Morace, A., Matsui, R., Yabuuchi, T., Miyanishi, K., Togashi, T., Inubushi, Y., Sueda, K., Ozaki, N., Kuramitsu, Y., L. Garcia, A., Fukami, K., Kluge, T., Kanasaki, M., Yamauchi, T., Yuji, Fukuda, Kishimoto, Y., Sakawa, Youichi, Ota, M., Matsumoto, Y., Rodel, M., Pikuz, T., Pirozhkov, Alexander, Egashira, S., Takumi, Minami, Sakai, K., Ishihara, D., Kuramoto, O., Maeda, K., Abe, Y., Nakamura, H., Morace, A., Matsui, R., Yabuuchi, T., Miyanishi, K., Togashi, T., Inubushi, Y., Sueda, K., Ozaki, N., Kuramitsu, Y., L. Garcia, A., Fukami, K., Kluge, T., Kanasaki, M., Yamauchi, T., Yuji, Fukuda, and Kishimoto, Y.

Abstract

We conduct SAXS measurement of sub-micron scale highly-ordered silicon-wire assembly targets (wire diameter: 500 nm, distance: 1 um, length: ~10 um, 15x3 array) to reveal temporal evolution of density profiles of 3D structure for the first time., International Conference on High Energy Density Science 2022

Published

2022

36. Hydrodynamics driven by ultrashort laser pulse: simulations and the optical pump—X-ray probe experiment

Author

Inogamov, N. A., Zhakhovsky, V. V., Hasegawa, N., Nishikino, M., Yamagiwa, M., Ishino, M., Agranat, M. B., Ashitkov, S. I., Faenov, A. Ya., Khokhlov, V. A., Ilnitsky, D. K., Petrov, Yu. V., Migdal, K. P., Pikuz, T. A., Takayoshi, S., Eyama, T., Kakimoto, N., Tomita, T., Baba, M., Minami, Y., Suemoto, T., and Kawachi, T.

Published

2015

37. Erratum: Using Diffuse Scattering to Observe X-Ray-Driven Nonthermal Melting [Phys. Rev. Lett. 126 , 015703 (2021)]

Author

Hartley, N. J., primary, Grenzer, J., additional, Huang, L., additional, Inubushi, Y., additional, Kamimura, N., additional, Katagiri, K., additional, Kodama, R., additional, Kon, A., additional, Lu, W., additional, Makita, M., additional, Matsuoka, T., additional, Nakajima, S., additional, Ozaki, N., additional, Pikuz, T., additional, Rode, A., additional, Sagae, D., additional, Schuster, A. K., additional, Tono, K., additional, Voigt, K., additional, Vorberger, J., additional, Yabuuchi, T., additional, McBride, E. E., additional, and Kraus, D., additional

Published

2022

38. 高強度 J-KAREN-P レーザーを用いた無衝突静電衝撃波によるイオン加速

Author

Pikuz, T., Morace, A., Kumar, R., Alkhimova, M.A., Mcllvenny, A., McCusker , O., Borghesi, M., Kotaro, Kondo, Pirozhkov, Alexander, Hiromitsu, Kiriyama, Takafumi, Asai, and Yuji, Fukuda

Abstract

関西光化学研究所の J-KAREN-P レーザーを CH または CHCl 薄膜ターゲットに照射し、 無衝突静電衝撃波イオン加速(ECS)の研究を行った。薄膜ターゲット(0.5~4.0μm)をプ レパルスまたはメインパルスの一部を取り出したイオンかパルスによりプラズマ化させる ことで初期プラズマを形成し、そこにメインパルス(プレパルスから数 ns 後)を入射する ことで ECS を生成した。ターゲットの厚さ、レーザーのスポット径、プレパルスとメイン パルスのコントラストなどを変化させることで初期プラズマを変化させて実験を行った。 計測にはトムソンパラボラ(加速イオン)、X 線分光器(プラズマ密度・温度)を使用した。, 第38回 プラズマ・核融合学会 年会

Published

2021

39. Study of Optical Emission During Spallative Ablation Induced by Soft X-Ray Laser Pulses

Author

Ishino, M., primary, Nishikino, M., additional, Hasegawa, N., additional, Pikuz, T., additional, Skobelev, I., additional, Faenov, A., additional, Yamagiwa, M., additional, and Kawachi, T., additional

Published

2015

40. Progress and Prospects of Coherent X-Ray Research Using High Power Lasers in Japan Atomic Energy Agency

Author

Kawachi, T., primary, Nishikino, M., additional, Sasaki, A., additional, Ishino, M., additional, Hasegawa, N., additional, Imazono, T., additional, Pikuz, T. A., additional, Faenov, A. Y., additional, Magnitskiy, M., additional, Maruyama, M., additional, Tomita, T., additional, Suemoto, T., additional, Pirozhkov, A. S., additional, Bulanov, S. V., additional, Kiriyama, H., additional, Kando, M., additional, Yamagiwa, M., additional, Kondo, K., additional, Bolton, P., additional, and Kato, Y., additional

Published

2015

41. Overview of the 10^22 Experiment with the J-KAREN-P laser

Author

Pirozhkov, Alexander, Sagisaka, Akito, Ogura, Koichi, Timur, Esirkepov, Gonzalez izquierdo, Bruno, N. Shatokhin, A., A. Vishnyakov, E., Armstrong, C., A. Pikuz, T., A. Alkhimova, M., A. Pikuz, S., Yan, W., M. Jeong, T., Singh, S., Hadjisolomou, P., Finke, O., Grittani, G., Nevrkla, M., Lazzarini, C., Velyhan, A., Hayakawa, Takehito, Fukuda, Yuuji, Kevin Koga, James, Ishino, Masahiko, Kondo, Kotaro, Miyasaka, Yasuhiro, Kon, Akira, Nishikino, Masaharu, O. Kolesnikov, A., N. Ragozin, E., Khikhlukha, D., P. Tsygvintsev, I., A. Gasilov, V., Kumar, D., Nejdl, J., Margarone, D., Sasorov, P., Weber, S., Kando, Masaki, Kiriyama, Hiromitsu, Korn, G., Neely, D., Kondo, Kiminori, Bulanov, Sergey, Kawachi, Tetsuya, Akito, Sagisaka, Koichi, Ogura, Takehito, Hayakawa, Yuji, Fukuda, Masahiko, Ishino, Kotaro, Kondo, Yasuhiro, Miyasaka, Akira, Kon, Masaharu, Nishikino, Masaki, Kando, Hiromitsu, Kiriyama, Kiminori, Kondo, and Tetsuya, Kawachi

Abstract

Ultra-high intensities open a way towards Terawatt and potentially Petawatt gamma-ray pulses in the so called Gamma Flare regime. We performed our first experiment towards this regime with the J-KAREN-P laser operating at intensities close to 10^22 W/cm^2. In this presentation I will overview the experiment, including very bright hard x-ray generation (sub-MeV to a few-MeV spectral range), high-order harmonic generation (30 to 70 eV), and multiple additional diagnostics revealing information on preplasma (properties of reflected 1st, 2nd, and 3rd harmonics and back-reflection). I will compare these results with the integrated HD and PIC simulations., OPTO-2021 Symposium on Photon and Beam Science

Published

2021

42. Generation of hard x-rays at intensities approaching 10^22 W/cm^2

Author

Pirozhkov, Alexander, Sagisaka, Akito, Ogura, Koichi, Timur, Esirkepov, Gonzalez izquierdo, Bruno, N. Shatokhin, A., A. Vishnyakov, E., Armstrong, C., A. Pikuz, T., A. Alkhimova, M., A. Pikuz, S., Yan, W., M. Jeong, T., Singh, S., Hadjisolomou, P., Finke, O., Grittani, G., Nevrkla, M., Lazzarini, C., Velyhan, A., Hayakawa, Takehito, Fukuda, Yuuji, Kevin Koga, James, Ishino, Masahiko, Kondo, Kotaro, Miyasaka, Yasuhiro, Kon, Akira, Nishikino, Masaharu, O. Kolesnikov, A., N. Ragozin, E., Khikhlukha, D., P. Tsygvintsev, I., A. Gasilov, V., Kumar, D., Nejdl, J., Margarone, D., Sasorov, P., Weber, S., Kando, Masaki, Kiriyama, Hiromitsu, Korn, G., Neely, D., Kondo, Kiminori, Bulanov, Sergey, Kawachi, Tetsuya, Akito, Sagisaka, Koichi, Ogura, Takehito, Hayakawa, Yuji, Fukuda, Masahiko, Ishino, Kotaro, Kondo, Yasuhiro, Miyasaka, Akira, Kon, Masaharu, Nishikino, Masaki, Kando, Hiromitsu, Kiriyama, Kiminori, Kondo, and Tetsuya, Kawachi

Abstract

We describe our experiment performed with the J-KAREN-P laser at the intensity approaching 10^22 W/cm^2. In particular, we present the results obtained with hard x-ray (0.1-3 MeV) spectrographs comprising 10 scintillators and a method to reconstruct the x-ray spectra., 3rd International Conference on Nuclear Photonics (NP2020)

Published

2021

43. Recent progress in x-ray spectral diagnostics of contrast dependent plasma at relativistic intensities of ~10^22 W/cm^2

Author

Pikuz, T., Alkhimova, M., Ryazantsev, S., Yu.Skobelev, I., Pikuz, S., Martynenko, A.S., Sedov, M.V., Shatokhin, A.N., Vishnyakov, E.A., Akito, Sagisaka, Koichi, Ogura, Gonzalez Izquierdo, B., Kotaro, Kondo, Yasuhiro, Miyasaka, Akira, Kon, Masahiko, Ishino, Masaharu, Nishikino, Timur, Esirkepov, Kevin Koga, James, Masaki, Kando, Hiromitsu, Kiriyama, Kiminori, Kondo, Masui, R., Kishimoto, Y., Ota, M., Takafumi, Asai, Kanasaki, M., Jinno, S., Kuramitsu, Y., Kodama, R., Tetsuya, Kawachi, Yuji, Fukuda, Pirozhkov, Alexander, and Sakawa, Y.

Abstract

At PW-class laser facilities pulse intensities of the order of 10^21 – 10^22 W/cm^2 can be reached by focusing high quality laser beams to spots of a few microns size. Under such conditions, during fs- time intervals a huge amount of optical energy is concentrated into a tiny volume and by the interaction with solid targets creates a plasma with high energy density. Such plasma can be sources of non-linear phenomena, among known and predicted by theory there is the acceleration to high energy of protons, ions, electrons and neutrons, generation of HOH and gamma-flare, creation of exotic states of hollow ions and WDM. The observed phenomena are defined by the type of target, laser energy and strongly depend on the prepulse condition. Achieving highly ionized states for elements with medium Z allows to effectively perform x-ray diagnostics of plasma parameters and preplasma conditions by means of high-resolution spectroscopy based on the analysis of spectra of H-like and He-like ions. Here we l present a review on the recent results on application of x-ray spectroscopic diagnostics of plasmas generated in the interaction of J-KAREN-P ultra-high intensity laser pulses with solid and clusters targets under conditions of different intrinsic laser contrast and under the cases of specially incorporated prepulse for controlled preplasma formation. Plasma parameters were evaluated by means of time integrated x-ray spectroscopic measurements and kinetic modeling using the code PrismSPECT. Certain line intensity relations, including the relations (Ly_a / He_b), (Ly_a / Ly_a satellites), relation between Ly_a satellites, as well as broadening and the shape of line, were used as the main tools for evaluation of plasma parameters. Each of the tools has preferred dependences on plasma electron temperature, electron density, electric and magnetic field strength. Four types of experiments are under consideration., 3rd International Conference on Nuclear Photonics NP2020

Published

2021

44. Contact X-ray microscopy of living cells by using LiF crystal as imaging detector

Author

REALE, L., BONFIGLI, F., LAI, A., FLORA, F., ALBERTANO, P., DI GIORGIO, M. L., MEZI, L., MONTEREALI, R. M., FAENOV, A., PIKUZ, T., ALMAVIVA, S., FRANCUCCI, M., GAUDIO, P., MARTELLUCCI, S., RICHETTA, M., and POMA, A.

Published

2015

45. Multiple diagnostics in laser-plasma experiment at ~10^22 W/cm^2

Author

Pirozhkov, Alexander, Sagisaka, Akito, Ogura, Koichi, Timur, Esirkepov, Gonzalez izquierdo, Bruno, N. Shatokhin, A., A. Vishnyakov, E., Armstrong, C., A. Pikuz, T., A. Alkhimova, M., A. Pikuz, S., Yan, W., M. Jeong, T., Singh, S., Hadjisolomou, P., Finke, O., Grittani, G., Nevrkla, M., Lazzarini, C., Velyhan, A., Hayakawa, Takehito, Fukuda, Yuuji, Kevin Koga, James, Ishino, Masahiko, Kondo, Kotaro, Miyasaka, Yasuhiro, Kon, Akira, Nishikino, Masaharu, O. Kolesnikov, A., N. Ragozin, E., Khikhlukha, D., P. Tsygvintsev, I., A. Gasilov, V., Kumar, D., Nejdl, J., Margarone, D., Sasorov, P., Weber, S., Kando, Masaki, Kiriyama, Hiromitsu, Korn, G., Neely, D., Kondo, Kiminori, Bulanov, Sergey, Kawachi, Tetsuya, Akito, Sagisaka, Koichi, Ogura, Takehito, Hayakawa, Yuji, Fukuda, Masahiko, Ishino, Kotaro, Kondo, Yasuhiro, Miyasaka, Akira, Kon, Masaharu, Nishikino, Masaki, Kando, Hiromitsu, Kiriyama, Kiminori, Kondo, and Tetsuya, Kawachi

Subjects

Astrophysics::High Energy Astrophysical Phenomena

Abstract

We present multi-diagnostic results from laser-plasma experiment at ~10^22 W/cm^2, including optical and high-order harmonics, back-reflection, soft x-rays, keV x-rays, and sub-MeV to MeV x-rays, simultaneously with important laser parameters. We discuss methods to find at-focus target position and compare intensity dependences., OPTICS & PHOTONICS International Congress 2021

Published

2021

46. X-ray spectroscopy of relativistic plasma with controlled preplasma formation at J-KAREN-P experiments

Author

Pikuz, T., A. Alkhimova, M., N. Ryazantsev, S., Yu. Skobelev, I., Pikuz, S., S. Martynenko, A., V. Sedov, M., N. Shatokhin, A., A. Vishnyakov, E., Akito, Sagisaka, Koichi, Ogura, Gonzalez Izquierdo, B., Kotaro, Kondo, Yasuhiro, Miyasaka, Akira, Kon, Masahiko, Ishino, Masaharu, Nishikino, Timur, Esirkepov, Kevin Koga, James, Masaki, Kando, Hiromitsu, Kiriyama, Kiminori, Kondo, Kodama, R., Tetsuya, Kawachi, Yuji, Fukuda, Pirozhkov, Alexander, Sakawa, Y., and Yuuji, Fukuda

Abstract

After recent upgrade of the Petawatt-class J-KEREN-P laser system the experiments with on-target relativistic intensity up to 10^22 W/cm^2 (pulse energy ~10 J, pulse length ~40 fs, focal spot down to 1.5 um) are routinely carried out at KPSI, QST. In general, for solid targets the plasma formation threshold is of ~10^10-10^12 W/cm^2, therefore the long ASE prepulse, short and ultrashort pedestal intensity crucially impact the formation of plasma conditions and the observed phenomena. It was demonstrated that there exists a strong dependence of the degree of Fe ionization on a laser prepulse, and that an effective generation of energetic, multiply-charged moderate- and high-Z ions can be driven only with laser pulses of ultra-high contrast. Here we report on the new experiments performed at J-KAREN-P laser with the tailored plasma density profile created by specially incorporated prepulse. For the prepulse the ~1/100 of the main pulse power was picked up and delivered to the target with controlled sub-nanosecond time interval prior to the main pulse. The prepulse was focused: (1) on the front of a stainless steel foil for the formation of downstream preplasma with conditions aiming the efficient generation of x-ray flare and high-order harmonics (experiment led by A.S. Pirozhkov); and (2) on the rear-side of a 4-Chlorosterene foil mimicking upstream preplasma, which has the necessary density profile for collisionless shock ion acceleration, when the main pulse is irradiated (experiment led by Y. Fukuda and Y. Sakawa). For both experiments, we present the detailed analysis of plasma parameters provided by means of high-resolution x-ray spectroscopic methods, based on emission characteristics of plasma in the spectral range of Ne-like Fe and H-like Cl ionization states, respectively., International Conference on High Energy Density Sciences (HEDS2021)

Published

2021

47. X-ray spectroscopy evidence of solid-density ultra-relativistic laser plasma in renewable micron-scale cryogenic clusters targets

Author

N. Ryazantsev, S., A. Pikuz, T., A. Pikuz, S., Kaji, T., Tanabe, H., Nakagawa, T., Takafumi, Asai, Kanasaki, M., Oda, K., Yamauchi, T., Jinno, S., Taguchi, T., K. Himeno, Iwasaki, K., Hihara, T., Sakai, K., Minami, T., Abe, Y., Tokiyasu, A., Kohri, H., Kuramitsu, Y., Sakawa, Y., Yasuhiro, Miyasaka, Kotaro, Kondo, Akira, Kon, Akito, Sagisaka, Koichi, Ogura, Pirozhkov, Alexander, Masaki, Kando, Kiminori, Kondo, Tetsuya, Kawachi, Hiromitsu, Kiriyama, Yuji, Fukuda, and Yuuji, Fukuda

Abstract

Recently it was shown that injection of gas preliminary cooled down to cryogenic temperatures is a promising way to produce micron-scale clusters. For example, in hydrogen clusters with the size up to ≈2 μm were produced via a conical nozzle at 25 K, 6 MPa. Micron scale clusters can be also created with another pre-cooled gases, for example Ar or Kr, but for other temperature values. So large clusters diameter value becomes comparable with a waist width of a laser beam produced by the J-KAREN-P laser facility. As a result, an experimental case can occur, when most of the laser energy is absorbed in a single cluster. Such situation can be considered as an interaction of a laser pulse with matter, state of which is close to solid-state. In the presentation plasma X-ray spectra features indicating the described case of high-intensity laser and large-scale-cluster interaction are discussed. They were observed experimentally during irradiation of cryogenic (T = 140 K – 220 K) Ar flows by ultra-intensive (I = 10^22 W/cm^2) femtosecond laser pulses generated by the J-KAREN-P laser. Registered X-ray spectra of produced plasma contains Ar XVIII Ly-α and Ar XVII He-α of comparable intensities. It should be noted that the Ar XVIII Ly-α line has been for the first time observed in laser-matter interaction experiments. It indicates that the density of irradiated matter is high enough to provide a rate of impact ionization process, which is sufficient to create a significant amount of H-like Ar ions. It is a challenge to reach such condition for a pure gas or small clusters. Thus, the observed spectra are considered as an evidence of a large micron cluster existing in the beam waist region., International Conference on High Energy Density Sciences (HEDS2021)

Published

2021

48. Using Diffuse Scattering to Observe X-Ray-Driven Nonthermal Melting

Author

(0000-0002-6268-2436) Hartley, N., Grenzer, J., Huang, L., Inubushi, Y., Kamimura, N., Katagiri, K., Kodama, R., Kon, A., Lu, W., Makita, M., Matsuoka, T., Nakajima, S., Ozaki, N., Pikuz, T., Rode, A. V., Sagae, D., (0000-0001-5489-5952) Schuster, A., Tono, K., Voigt, K., (0000-0001-5926-9192) Vorberger, J., Yabuuchi, T., McBride, E. E., (0000-0002-6350-4180) Kraus, D., (0000-0002-6268-2436) Hartley, N., Grenzer, J., Huang, L., Inubushi, Y., Kamimura, N., Katagiri, K., Kodama, R., Kon, A., Lu, W., Makita, M., Matsuoka, T., Nakajima, S., Ozaki, N., Pikuz, T., Rode, A. V., Sagae, D., (0000-0001-5489-5952) Schuster, A., Tono, K., Voigt, K., (0000-0001-5926-9192) Vorberger, J., Yabuuchi, T., McBride, E. E., and (0000-0002-6350-4180) Kraus, D.

Abstract

We present results from the SPring-8 Angstrom Compact free electron LAser facility, where we used a high intensity (∼10^20 W/cm2) x-ray pump x-ray probe scheme to observe changes in the ionic structure of silicon induced by x-ray heating of the electrons. By avoiding Laue spots in the scattering signal from a single crystalline sample, we observe a rapid rise in diffuse scattering and a transition to a disordered, liquidlike state with a structure significantly different from liquid silicon. The disordering occurs within 100 fs of irradiation, a timescale that agrees well with first principles simulations, and is faster than that predicted by purely inertial behavior, suggesting that both the phase change and disordered state reached are dominated by Coulomb forces. This method is capable of observing liquid scattering without masking signal from the ambient solid, allowing the liquid structure to be measured throughout and beyond the phase change.

Published

2021

49. X-ray generation at intensities approaching 10^22 W/cm^2

Author

Pirozhkov, Alexander, Sagisaka, Akito, Ogura, Koichi, Timur, Esirkepov, Gonzalez izquierdo, Bruno, N. Shatokhin, A., A. Vishnyakov, E., Armstrong, C., A. Pikuz, T., A. Alkhimova, M., A. Pikuz, S., Yan, W., M. Jeong, T., Singh, S., Hadjisolomou, P., Finke, O., Grittani, G., Nevrkla, M., Lazzarini, C., Velyhan, A., Hayakawa, Takehito, Fukuda, Yuuji, Kevin Koga, James, Ishino, Masahiko, Kondo, Kotaro, Miyasaka, Yasuhiro, Kon, Akira, Nishikino, Masaharu, O. Kolesnikov, A., N. Ragozin, E., Khikhlukha, D., P. Tsygvintsev, I., A. Gasilov, V., Kumar, D., Nejdl, J., Margarone, D., Sasorov, P., Weber, S., Kando, Masaki, Kiriyama, Hiromitsu, Korn, G., Neely, D., Kondo, Kiminori, Bulanov, Sergey, and Kawachi, Tetsuya

Abstract

Generation of bright sources of hard and soft x-rays is one of the most promising applications of high-power lasers. We report on our first experiment on achieving ultra-high on-target intensities, reaching efficient conversion of laser radiation to hard x-rays (towards the "Gamma Flash" regime [1-3]), and generating intense high-order harmonics [4]. Our international team (Japan, Czech Republic, Russia, UK) used the J-KAREN-P laser facility at KPSI QST, Japan [5-8] and irradiated solid targets with intensities close to 1022 W/cm2. We employed a broad range of diagnostics, including laser, plasma, secondary radiation (from NIR to MeV x-rays) and particle (e-, p+) diagnostics, and controlled the preplasma scale length, which is a critical parameter for both hard x-ray [1,3] and harmonic generation [4]. Here we overview the experiment and dedicated simulations, and show first results on hard x-ray and harmonic generation, x-ray spectroscopy, and preplasma analysis. We thank the J-KAREN-P laser operation group. We acknowledge financial support from ELI-Beamlines, High Field Initiative Project (CZ.02.1.01/0.0/0.0/15\_003/0000449) from the European Regional Development Fund, JSPS JP 17F17811 and 19H00669, QST-IRI, and QST Director Funds 創成的研究#16 and #20. [1]T. Nakamura, et al., Phys. Rev. Lett., 2012, 108 195001. [2]C. P. Ridgers, et al., Phys. Rev. Lett. 2012, 108, 165006. [3]K. V. Lezhnin, P. V. Sasorov, G. Korn, and S. V. Bulanov, Phys. Plasmas, 2018, 25, 123105. [4]U. Teubner and P. Gibbon, Rev. Mod. Phys., 2009, 81, 445. [5]A. S. Pirozhkov, et al., Opt. Express, 2017, 25, 20486. [6]H. Kiriyama, et al., Opt. Lett., 2018, 43, 2595. [7]H. Kiriyama, et al., Opt. Lett., 2020, 45, 1100. [8]H. Kiriyama, et al., Crystals., 2020, 10, 783., International Conference on X-Ray Laser 2020

Published

2020

50. Overview of the 10^22 Experiment

Author

Pirozhkov, Alexander, Sagisaka, Akito, Ogura, Koichi, Timur, Esirkepov, Gonzalez izquierdo, Bruno, N. Shatokhin, A., A. Vishnyakov, E., Armstrong, C., A. Pikuz, T., A. Alkhimova, M., A. Pikuz, S., Yan, W., M. Jeong, T., Singh, S., Hadjisolomou, P., Finke, O., Grittani, G., Nevrkla, M., Lazzarini, C., Velyhan, A., Hayakawa, Takehito, Fukuda, Yuuji, Kevin Koga, James, Ishino, Masahiko, Kondo, Kotaro, Miyasaka, Yasuhiro, Kon, Akira, Nishikino, Masaharu, O. Kolesnikov, A., N. Ragozin, E., Khikhlukha, D., P. Tsygvintsev, I., A. Gasilov, V., Kumar, D., Nejdl, J., Margarone, D., Sasorov, P., Weber, S., Kando, Masaki, Kiriyama, Hiromitsu, Korn, G., Neely, D., Kondo, Kiminori, Bulanov, Sergey, and Kawachi, Tetsuya

Abstract

We present an overview of our recent experiment on achieving ultra-high on-target intensities, reaching efficient conversion of laser radiation to hard x-rays ("Gamma Flash"), and generating intense coherent soft x-rays (high-order harmonics). Our international team used the J-KAREN-P laser facility at KPSI QST and irradiated solid targets with intensities close to 1022 W/cm2. We employed a broad range of diagnostics, including laser, plasma, secondary radiation (from NIR to MeV x-rays) and particle (e-, p+) diagnostics, and controlled preplasma using several laser contrast modes and artificial prepulse. In this presentation we overview the experiment and simulations dedicated to it, and show first results on hard x-ray and harmonic generation, x-ray spectroscopy, and preplasma analysis., Opto-2020 Symposium on Photon and Beam Science

Published

2020