Your search keyword '"Danila Khikhlukha"' showing total 9 results

1. HELL: High-Energy Electrons by Laser Light, a User-Oriented Experimental Platform at ELI Beamlines

Author

Tadzio Levato, Stefano Bonora, Gabriele Maria Grittani, Carlo Maria Lazzarini, Muhammad Fahad Nawaz, Michal Nevrkla, Leonardo Villanova, Roberto Ziano, Silvano Bassanese, Nadezhda Bobrova, Katia Casarin, Edwin Chacon-Golcher, Yanjun Gu, Danila Khikhlukha, Daniel Kramer, Marco Lonza, Daniele Margarone, Veronika Olšovcová, Marcin Rosinski, Bedrich Rus, Pavel Sasorov, Roberto Versaci, Agnieska Zaraś-Szydłowska, Sergei V. Bulanov, and Georg Korn

Subjects

LWFA, laser-plasma acceleration, laser-driven electron acceleration, ultrahigh intensity laser-matter interaction, laser-electron collider, laser counter-propagation, ELI Beamlines, HELL, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Laser wake field acceleration (LWFA) is an efficient method to accelerate electron beams to high energy. This is a benefit in research infrastructures where a multidisciplinary environment can benefit from the different secondary sources enabled, having the opportunity to extend the range of applications that is accessible and to develop new ideas for fundamental studies. The ELI Beamline project is oriented to deliver such beams to the scientific community both for applied and fundamental research. The driver laser is a Ti:Sa diode-pumped system , running at a maximum performance of 10 Hz, 30 J, and 30 fs. The possibilities to setup experiments using different focal lengths parabolas, as well as the possibility to counter-propagate a second laser beam intrinsically synchronized, are considered in the electron acceleration program. Here, we review the laser-driven electron acceleration experimental platform under implementation at ELI Beamlines, the HELL (High-energy Electrons by Laser Light) experimental platform .

Published

2018

2. Using Spherical-Harmonics Expansions for Optics Surface Reconstruction from Gradients

Author

Juan Manuel Solano-Altamirano, Alejandro Vázquez-Otero, Danila Khikhlukha, Raquel Dormido, and Natividad Duro

Subjects

wavefront reconstruction from gradients, surface reconstruction from gradients, spherical harmonics, zernike-polynomials, algorithm, Chemical technology, TP1-1185

Abstract

In this paper, we propose a new algorithm to reconstruct optics surfaces (aka wavefronts) from gradients, defined on a circular domain, by means of the Spherical Harmonics. The experimental results indicate that this algorithm renders the same accuracy, compared to the reconstruction based on classical Zernike polynomials, using a smaller number of polynomial terms, which potentially speeds up the wavefront reconstruction. Additionally, we provide an open-source C++ library, released under the terms of the GNU General Public License version 2 (GPLv2), wherein several polynomial sets are coded. Therefore, this library constitutes a robust software alternative for wavefront reconstruction in a high energy laser field, optical surface reconstruction, and, more generally, in surface reconstruction from gradients. The library is a candidate for being integrated in control systems for optical devices, or similarly to be used in ad hoc simulations. Moreover, it has been developed with flexibility in mind, and, as such, the implementation includes the following features: (i) a mock-up generator of various incident wavefronts, intended to simulate the wavefronts commonly encountered in the field of high-energy lasers production; (ii) runtime selection of the library in charge of performing the algebraic computations; (iii) a profiling mechanism to measure and compare the performance of different steps of the algorithms and/or third-party linear algebra libraries. Finally, the library can be easily extended to include additional dependencies, such as porting the algebraic operations to specific architectures, in order to exploit hardware acceleration features.

Published

2017

3. Laser Spot Detection Based on Reaction Diffusion

Author

Alejandro Vázquez-Otero, Danila Khikhlukha, J. M. Solano-Altamirano, Raquel Dormido, and Natividad Duro

Subjects

reaction diffusion models, Turing patterns, reaction diffusion computers, reaction diffusion computation, Fitzhugh-Nagumo model, laser spot position, laser spot detection, laser beam detection, Chemical technology, TP1-1185

Abstract

Center-location of a laser spot is a problem of interest when the laser is used for processing and performing measurements. Measurement quality depends on correctly determining the location of the laser spot. Hence, improving and proposing algorithms for the correct location of the spots are fundamental issues in laser-based measurements. In this paper we introduce a Reaction Diffusion (RD) system as the main computational framework for robustly finding laser spot centers. The method presented is compared with a conventional approach for locating laser spots, and the experimental results indicate that RD-based computation generates reliable and precise solutions. These results confirm the flexibility of the new computational paradigm based on RD systems for addressing problems that can be reduced to a set of geometric operations.

Published

2016

4. Imprint of the stochastic nature of photon emission by electrons on the proton energy spectra in the laser-plasma interaction

Author

Kun Xue, Georg Korn, Zhongfeng Xu, Danila Khikhlukha, Wenchao Yan, Sergei V. Bulanov, Feng Wan, Karen Zaven Hatsagortsyan, Yongtao Zhao, Zhen-Ke Dou, and Jian-Xing Li

Subjects

Physics, Photon, Monte Carlo method, FOS: Physical sciences, Plasma, Electron, Condensed Matter Physics, Laser, 01 natural sciences, Spectral line, Physics - Plasma Physics, 010305 fluids & plasmas, law.invention, Pulse (physics), Plasma Physics (physics.plasm-ph), Nuclear Energy and Engineering, law, 0103 physical sciences, Physics::Accelerator Physics, Atomic physics, 010306 general physics, Quantum

Abstract

The impact of stochasticity effects (SEs) in photon emissions on the proton energy spectra during laser-plasma interaction is theoretically investigated in the quantum radiation-dominated regime, which may facilitate SEs experimental observation. We calculate the photon emissions quantum mechanically and the plasma dynamics semiclassically via two-dimensional particle-in-cell simulations. An ultrarelativistic plasma generated and driven by an ultraintense laser pulse head-on collides with another strong laser pulse, which decelerates the electrons due to radiation-reaction effect and results in a significant compression of the proton energy spectra because of the charge separation force. In the considered regime the SEs are demonstrated in the shift of the mean energy of the protons up to hundreds of MeV. This effect is robust with respect to the laser and target parameters and measurable in soon available strong laser facilities.

Published

2019

5. Plasma formation in noncircular capillary discharges (Conference Presentation)

Author

Stepan Bulanov, A. S. Boldarev, Danila Khikhlukha, Gennadiy Bagdasarov, S. V. Bulanov, Anthony Gonsalves, Pavel V. Sasorov, Georg Korn, Wim Leemans, Carlo Benedetti, Daniele Margarone, O. G. Olkhovskaya, and V. A. Gasilov

Subjects

Physics, law, Capillary action, Plasma diagnostics, Plasma, Electron, Atomic physics, Magnetohydrodynamics, Plasma acceleration, Laser, Waveguide, law.invention

Abstract

For several decades the capillary discharges have been under intensive investigations due to various promising applications, e.g. for the laser electron accelerators as well as for the X-ray lasers [1,2]. A major portion of the experiments were done with circular cross-section capillaries. An appropriate theoretical and numerical study of circular capillaries can be greatly simplified to a 1D model [3] assuming rotational and axial symmetries of the plasma flow in a long thin channel. On the other hand, studying capillaries with non-circular cross-section [4], which have been attracting substantially less attention, requires more complicated 2D models. Such capillaries, for example, square one, possess several advantages related to their fabrication as well as for plasma diagnostics The aim of our work is to compare the plasma density and temperature distributions formed at the quasistationary stage of the discharge. We present the results of MHD simulations of hydrogen-filled capillary discharges with circular and rectangular cross-sections under almost the same conditions characterizing the initial configurations and the external electric circuit. The simulation parameters are choosen to correspond to the capillary discharge based waveguide for the laser wakefield accelerator [5]. Bibliography [1] Leemans W. P. et al 2014 Phys. Rev. Lett. 113 245002 [2] Benware B. R. et al 1998 Phys. Rev. Lett. 81 5804 [3] Bobrova N. A. et al 2001 Phys. Rev. E 65 016407 [4] Gonsalves A. J. et al 2007 Phys. Rev. Lett. 98 025002 [5] Esarey E. et al 2009 Rev. Mod. Phys. 81 1229

Published

2017

6. Laser Spot Detection Based on Reaction Diffusion

Author

Danila Khikhlukha, Raquel Dormido, J. M. Solano-Altamirano, N. Duro, and Alejandro Vázquez-Otero

Subjects

0301 basic medicine, Computer science, reaction diffusion computation, reaction diffusion models, Turing patterns, reaction diffusion computers, Fitzhugh-Nagumo model, laser spot position, laser spot detection, laser beam detection, lcsh:Chemical technology, computer.software_genre, 01 natural sciences, Biochemistry, Article, 010305 fluids & plasmas, Analytical Chemistry, law.invention, Set (abstract data type), 03 medical and health sciences, Quality (physics), law, 0103 physical sciences, Reaction–diffusion system, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Flexibility (engineering), Laser, Atomic and Molecular Physics, and Optics, 030104 developmental biology, Data mining, Algorithm, computer

Abstract

Center-location of a laser spot is a problem of interest when the laser is used for processing and performing measurements. Measurement quality depends on correctly determining the location of the laser spot. Hence, improving and proposing algorithms for the correct location of the spots are fundamental issues in laser-based measurements. In this paper we introduce a Reaction Diffusion (RD) system as the main computational framework for robustly finding laser spot centers. The method presented is compared with a conventional approach for locating laser spots, and the experimental results indicate that RD-based computation generates reliable and precise solutions. These results confirm the flexibility of the new computational paradigm based on RD systems for addressing problems that can be reduced to a set of geometric operations.

Published

2016

7. Using Spherical-Harmonics Expansions for Optics Surface Reconstruction from Gradients

Author

J. M. Solano-Altamirano, N. Duro, Raquel Dormido, Alejandro Vázquez-Otero, and Danila Khikhlukha

Subjects

Polynomial, Zernike polynomials, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 02 engineering and technology, lcsh:Chemical technology, 01 natural sciences, Biochemistry, Article, Analytical Chemistry, 010309 optics, symbols.namesake, Optics, surface reconstruction from gradients, 0103 physical sciences, lcsh:TP1-1185, Electrical and Electronic Engineering, Instrumentation, Wavefront, wavefront reconstruction from gradients, algorithm, business.industry, spherical harmonics, Spherical harmonics, zernike-polynomials, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, Algebraic operation, Linear algebra, symbols, Hardware acceleration, 0210 nano-technology, business, Surface reconstruction

Abstract

In this paper, we propose a new algorithm to reconstruct optics surfaces (aka wavefronts) from gradients, defined on a circular domain, by means of the Spherical Harmonics. The experimental results indicate that this algorithm renders the same accuracy, compared to the reconstruction based on classical Zernike polynomials, using a smaller number of polynomial terms, which potentially speeds up the wavefront reconstruction. Additionally, we provide an open-source C++ library, released under the terms of the GNU General Public License version 2 (GPLv2), wherein several polynomial sets are coded. Therefore, this library constitutes a robust software alternative for wavefront reconstruction in a high energy laser field, optical surface reconstruction, and, more generally, in surface reconstruction from gradients. The library is a candidate for being integrated in control systems for optical devices, or similarly to be used in ad hoc simulations. Moreover, it has been developed with flexibility in mind, and, as such, the implementation includes the following features: (i) a mock-up generator of various incident wavefronts, intended to simulate the wavefronts commonly encountered in the field of high-energy lasers production; (ii) runtime selection of the library in charge of performing the algebraic computations; (iii) a profiling mechanism to measure and compare the performance of different steps of the algorithms and/or third-party linear algebra libraries. Finally, the library can be easily extended to include additional dependencies, such as porting the algebraic operations to specific architectures, in order to exploit hardware acceleration features.

Published

2017

8. Imprint of the stochastic nature of photon emission by electrons on the proton energy spectra in the laser-plasma interaction.

Author

Feng Wan, Kun Xue, Zhen-Ke Dou, Karen Z Hatsagortsyan, Wenchao Yan, Danila Khikhlukha, Sergei V Bulanov, Georg Korn, Yong-Tao Zhao, Zhong-Feng Xu, and Jian-Xing Li

Subjects

PHOTON emission, ELECTRON emission, LASER-plasma interactions, PROTONS, QUANTUM plasmas, PLASMA dynamics, LASER plasmas

Abstract

The impact of stochasticity effects (SEs) in photon emissions on the proton energy spectra during laser-plasma interaction is theoretically investigated in the quantum radiation-dominated regime. We calculate the photon emissions quantum mechanically and the plasma dynamics semiclassically via two-dimensional particle-in-cell simulations. An ultrarelativistic plasma generated and driven by an ultraintense laser pulse head-on collides with another strong laser pulse, which decelerates the electrons due to radiation-reaction effect and results in a significant compression of the proton energy spectra because of the charge separation force. In the considered regime the SEs are demonstrated in the shift of the mean energy of the protons up to hundreds of MeV. This effect is robust with respect to the laser and target parameters and measurable in soon available strong laser facilities. [ABSTRACT FROM AUTHOR]

Published

2019

9. HELL: High-Energy Electrons by Laser Light, a User-Oriented Experimental Platform at ELI Beamlines

Author

Stefano Bonora, Leonardo Villanova, G. Grittani, Bedrich Rus, Tadzio Levato, Georg Korn, Michal Nevrkla, Sergei V. Bulanov, Marcin Rosinski, Marco Lonza, Daniele Margarone, Daniel B. Kramer, Roberto Versaci, C. M. Lazzarini, Yanjun Gu, Roberto Ziano, K. Casarin, Danila Khikhlukha, Agnieska Zaraś-Szydlowska, N. A. Bobrova, Pavel V. Sasorov, S. Bassanese, Muhammad Fahad Nawaz, Veronika Olšovcová, and Edwin Chacon-Golcher

Subjects

High energy, Computer science, laser-driven electron acceleration, ELI Beamlines, laser-plasma acceleration, Electron, laser-electron collider, 7. Clean energy, 01 natural sciences, lcsh:Technology, 010305 fluids & plasmas, law.invention, lcsh:Chemistry, Acceleration, Optics, law, ultrahigh intensity laser-matter interaction, 0103 physical sciences, Focal length, General Materials Science, 010306 general physics, Instrumentation, lcsh:QH301-705.5, Laser light, Fluid Flow and Transfer Processes, Range (particle radiation), business.industry, lcsh:T, Process Chemistry and Technology, General Engineering, Laser, lcsh:QC1-999, Computer Science Applications, laser counter-propagation, Beamline, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, HELL, LWFA, business, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

Laser wake field acceleration (LWFA) is an efficient method to accelerate electron beams to high energy. This is a benefit in research infrastructures where a multidisciplinary environment can benefit from the different secondary sources enabled, having the opportunity to extend the range of applications that is accessible and to develop new ideas for fundamental studies. The ELI Beamline project is oriented to deliver such beams to the scientific community both for applied and fundamental research. The driver laser is a Ti:Sa diode-pumped system , running at a maximum performance of 10 Hz, 30 J, and 30 fs. The possibilities to setup experiments using different focal lengths parabolas, as well as the possibility to counter-propagate a second laser beam intrinsically synchronized, are considered in the electron acceleration program. Here, we review the laser-driven electron acceleration experimental platform under implementation at ELI Beamlines, the HELL (High-energy Electrons by Laser Light) experimental platform .