Your search keyword '"Naren Ratan"' showing total 10 results

1. Preparations for a European RD roadmap for an inertial fusion demo reactor

Author

P. Allan, R. J. Leeper, Peter Norreys, Paul A. Bradley, S. A. Yi, J. Luis, Ramy Aboushelbaya, James Sadler, Robert R. Peterson, Kirk Flippo, Kevin Glize, M. G. Ramsay, Robert Bingham, Luke Ceurvorst, B. Spiers, Raoul Trines, N. Sircombe, Naren Ratan, Brian Haines, R. H. W. Wang, J. Fyrth, L. Hobbs, M. W. Mayr, C. R. D. Brown, E. Floyd, R. E. Olson, Steven James, John Kline, Jonathan Skidmore, Alex Zylstra, M. P. Hill, R. W. Paddock, and A. F. Savin

Subjects

High-gain antenna, Inertial frame of reference, General Mathematics, General Physics and Astronomy, Auxiliary heating, fast ignition, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, law.invention, IFE Roadmap, law, 0103 physical sciences, auxiliary heating, 010306 general physics, Inertial confinement fusion, QC, Fusion, General Engineering, inertial confinement fusion, Articles, Fusion power, Ignition system, Systems engineering, high-energy density plasma physics, inertial fusion energy, Research Article

Abstract

A European consortium of 15 laboratories across nine nations have worked together under the EUROFusion Enabling Research grants for the past decade with three principle objectives. These are: (a) investigating obstacles to ignition on megaJoule-class laser facilities; (b) investigating novel alternative approaches to ignition, including basic studies for fast ignition (both electron and ion-driven), auxiliary heating, shock ignition, etc.; and (c) developing technologies that will be required in the future for a fusion reactor. A brief overview of these activities, presented here, along with new calculations relates the concept of auxiliary heating of inertial fusion targets, and provides possible future directions of research and development for the updated European Roadmap that is due at the end of 2020. This article is part of a discussion meeting issue ‘Prospects for high gain inertial fusion energy (part 2)’.

Published

2020

2. Whole-beam self-focusing in fusion-relevant plasma

Author

Ben Spiers, L. Hobbs, M. P. Hill, N. Sircombe, J. Luis, M. G. Ramsay, A. F. Savin, R. W. Paddock, Luke Ceurvorst, Peter Norreys, P. Allan, Steven James, M. W. Mayr, Ramy Aboushelbaya, R. H. W. Wang, C. R. D. Brown, E. Floyd, J. Fyrth, Naren Ratan, and Jonathan Skidmore

Subjects

laser–plasma interactions, proton radiography, General Mathematics, General Physics and Astronomy, fast ignition, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, law.invention, Optics, law, 0103 physical sciences, 010306 general physics, plasma channelling, Inertial confinement fusion, Physics, business.industry, General Engineering, inertial confinement fusion, Self-focusing, Plasma, Articles, Fusion power, Laser, Magnetic field, Ignition system, Interferometry, synthetic diagnostics, business, Research Article

Abstract

Fast ignition inertial confinement fusion requires the production of a low-density channel in plasma with density scale-lengths of several hundred microns. The channel assists in the propagation of an ultra-intense laser pulse used to generate fast electrons which form a hot spot on the side of pre-compressed fusion fuel. We present a systematic characterization of an expanding laser-produced plasma using optical interferometry, benchmarked against three-dimensional hydrodynamic simulations. Magnetic fields associated with channel formation are probed using proton radiography, and compared to magnetic field structures generated in full-scale particle-in-cell simulations. We present observations of long-lived, straight channels produced by the Habara–Kodama–Tanaka whole-beam self-focusing mechanism, overcoming a critical barrier on the path to realizing fast ignition. This article is part of a discussion meeting issue ‘Prospects for high gain inertial fusion energy (part 2)’.

Published

2020

3. Attosecond-scale absorption at extreme intensities

Author

Maris Serzans, R. M. G. M. Trines, Luke Ceurvorst, A. J. Ross, A. F. Savin, Naren Ratan, Robert Bingham, Alexander Robinson, B. Spiers, and Peter Norreys

Subjects

Physics, Extreme Light Infrastructure, Attosecond, Scale (descriptive set theory), Plasma, Condensed Matter Physics, Laser, 01 natural sciences, 010305 fluids & plasmas, law.invention, Computational physics, law, Null vector, 0103 physical sciences, Atomic physics, 010306 general physics, Absorption (electromagnetic radiation), Scaling, QC

Abstract

A novel non-ponderomotive absorption mechanism, originally presented by Baeva et al. [Phys. Plasmas 18, 056702 (2011)] in one dimension, is extended into higher dimensions for the first time. This absorption mechanism, the Zero Vector Potential (ZVP), is expected to dominate the interactions of ultra-intense laser pulses with critically over-dense plasmas such as those that are expected with the Extreme Light Infrastructure laser systems. It is shown that the mathematical form of the ZVP mechanism and its key scaling relations found by Baeva et al. in 1D are identically reproduced in higher dimensions. The two dimensional particle-in-cell simulations are then used to validate both the qualitative and quantitative predictions of the theory.

Published

2017

4. Optimization of plasma amplifiers

Author

Luis O. Silva, Max Tabak, Frederico Fiuza, Naren Ratan, Muhammad Kasim, E. Paulo Alves, Dustin Froula, Raoul Trines, Dan Haberberger, A. Davies, Robert Bingham, Luke Ceurvorst, S. Bucht, James Sadler, and Peter Norreys

Subjects

Chirped pulse amplification, Materials science, Amplifier, Plasma, Laser, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Computational physics, Pulse (physics), law.invention, symbols.namesake, law, 0103 physical sciences, symbols, Coherence (signal processing), 010306 general physics, Raman spectroscopy, Energy (signal processing), QC

Abstract

Plasma amplifiers offer a route to side-step limitations on chirped pulse amplification and generate laser pulses at the power frontier. They compress long pulses by transferring energy to a shorter pulse via the Raman or Brillouin instabilities. We present an extensive kinetic numerical study of the three-dimensional parameter space for the Raman case. Further particle-in-cell simulations find the optimal seed pulse parameters for experimentally relevant constraints. The high-efficiency self-similar behavior is observed only for seeds shorter than the linear Raman growth time. A test case similar to an upcoming experiment at the Laboratory for Laser Energetics is found to maintain good transverse coherence and high-energy efficiency. Effective compression of a $10\phantom{\rule{0.16em}{0ex}}\mathrm{kJ}$, nanosecond-long driver pulse is also demonstrated in a 15-cm-long amplifier.

Published

2017

5. Machine learning applied to proton radiography of high-energy-density plasmas

Author

Luke Ceurvorst, Raoul Trines, James Sadler, Naren Ratan, M. C. Levy, Muhammad Kasim, Robert Bingham, Nicholas F. Y. Chen, and Peter Norreys

Subjects

Physics, Field (physics), Proton, 3D reconstruction, Magnetic reconnection, 01 natural sciences, Noise (electronics), 010305 fluids & plasmas, Magnetic field, Computational physics, Nonlinear system, Nuclear magnetic resonance, 0103 physical sciences, Physics::Accelerator Physics, Tomography, 010306 general physics

Abstract

Proton radiography is a technique extensively used to resolve magnetic field structures in high-energy-density plasmas, revealing a whole variety of interesting phenomena such as magnetic reconnection and collisionless shocks found in astrophysical systems. Existing methods of analyzing proton radiographs give mostly qualitative results or specific quantitative parameters, such as magnetic field strength, and recent work showed that the line-integrated transverse magnetic field can be reconstructed in specific regimes where many simplifying assumptions were needed. Using artificial neural networks, we demonstrate for the first time 3D reconstruction of magnetic fields in the nonlinear regime, an improvement over existing methods, which reconstruct only in 2D and in the linear regime. A proof of concept is presented here, with mean reconstruction errors of less than 5% even after introducing noise. We demonstrate that over the long term, this approach is more computationally efficient compared to other techniques. We also highlight the need for proton tomography because (i) certain field structures cannot be reconstructed from a single radiograph and (ii) errors can be further reduced when reconstruction is performed on radiographs generated by proton beams fired in different directions.

Published

2017

6. Quantitative shadowgraphy and proton radiography for large intensity modulations

Author

Peter Norreys, Malte C. Kaluza, Muhammad Kasim, James Sadler, Nicholas F. Y. Chen, Luke Ceurvorst, Robert Bingham, A. Sävert, Raoul Trines, Philip Burrows, and Naren Ratan

Subjects

Toroid, Computer science, business.industry, Process (computing), FOS: Physical sciences, 020207 software engineering, 02 engineering and technology, Plasma, Computational Physics (physics.comp-ph), Shadowgraphy, Computational geometry, 01 natural sciences, Physics - Plasma Physics, Magnetic field, Plasma Physics (physics.plasm-ph), Nonlinear system, Optics, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, 010306 general physics, business, Physics - Computational Physics, Intensity modulation, QC

Abstract

Shadowgraphy is a technique widely used to diagnose objects or systems in various fields in physics and engineering. In shadowgraphy, an optical beam is deflected by the object and then the intensity modulation is captured on a screen placed some distance away. However, retrieving quantitative information from the shadowgrams themselves is a challenging task because of the non-linear nature of the process. Here, a novel method to retrieve quantitative information from shadowgrams, based on computational geometry, is presented for the first time. This process can also be applied to proton radiography for electric and magnetic field diagnosis in high-energy-density plasmas and has been benchmarked using a toroidal magnetic field as the object, among others. It is shown that the method can accurately retrieve quantitative parameters with error bars less than 10%, even when caustics are present. The method is also shown to be robust enough to process real experimental results with simple pre- and post-processing techniques. This adds a powerful new tool for research in various fields in engineering and physics for both techniques.

Published

2017

7. Mitigating the hosing instability in relativistic laser-plasma interactions

Author

Robbie Scott, Raoul Trines, Naren Ratan, Marija Vranic, Luke Ceurvorst, M. Skramic, M. C. Levy, Luis O. Silva, Peter Norreys, Muhammad Kasim, James Sadler, and Taiwu Huang

Subjects

Physics, General Physics and Astronomy, Mechanics, Plasma, Parameter space, Space (mathematics), Laser, 01 natural sciences, Instability, 010305 fluids & plasmas, law.invention, Planar, law, Physics::Plasma Physics, 0103 physical sciences, Physics::Space Physics, 010306 general physics, Inertial confinement fusion, Line (formation)

Abstract

A new physical model of the hosing instability that includes relativistic laser pulses and moderate densities is presented and derives the density dependence of the hosing equation. This is tested against two-dimensional particle-in-cell simulations. These simulations further examine the feasibility of using multiple pulses to mitigate the hosing instability in a Nd:glass-type parameter space. An examination of the effects of planar versus cylindrical exponential density gradients on the hosing instability is also presented. The results show that strongly relativistic pulses and more planar geometries are capable of mitigating the hosing instability which is in line with the predictions of the physical model.

Published

2016

8. Quantitative single shot and spatially resolved plasma wakefield diagnostics

Author

Matthew Wing, M. C. Levy, Philip Burrows, Luke Ceurvorst, James Sadler, Naren Ratan, J. Holloway, Robert Bingham, Raoul Trines, Peter Norreys, and Muhammad Kasim

Subjects

Nuclear and High Energy Physics, Photon, Physics and Astronomy (miscellaneous), 01 natural sciences, 010305 fluids & plasmas, law.invention, Acceleration, Optics, Physics::Plasma Physics, law, 0103 physical sciences, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, Coordination and Communication [13.1], 010306 general physics, QC, Physics, business.industry, Surfaces and Interfaces, Plasma, Plasma acceleration, Laser, Accelerators and Storage Rings, Novel Acceleration Techniques (ANAC2) [13], Pulse (physics), Modulation, Physics::Space Physics, lcsh:QC770-798, Physics::Accelerator Physics, business, Frequency modulation

Abstract

Diagnosing plasma conditions can give great advantages in optimizing plasma wakefield accelerator experiments. One possible method is that of photon acceleration. By propagating a laser probe pulse through a plasma wakefield and extracting the imposed frequency modulation, one can obtain an image of the density modulation of the wakefield. In order to diagnose the wakefield parameters at a chosen point in the plasma, the probe pulse crosses the plasma at oblique angles relative to the wakefield. In this paper, mathematical expressions relating the frequency modulation of the laser pulse and the wakefield density profile of the plasma for oblique crossing angles are derived. Multidimensional particle-in-cell simulation results presented in this paper confirm that the frequency modulation profiles and the density modulation profiles agree to within 10%. Limitations to the accuracy of the measurement are discussed in this paper. This technique opens new possibilities to quantitatively diagnose the plasma wakefield density at known positions within the plasma column.

Published

2015

9. Wakefields in a cluster plasma

Author

Raoul Trines, P. P. Rajeev, A. F. Savin, Luis O. Silva, R. H. W. Wang, Ricardo Fonseca, Naren Ratan, D. R. Symes, Peter Norreys, M. W. Mayr, Muhammad Kasim, Nicolas Bourgeois, James Sadler, A. J. Ross, Matthew Wing, Kevin Glize, Luke Ceurvorst, B. Spiers, Philip Burrows, F. Keeble, J. Holloway, Ramy Aboushelbaya, and Robert Bingham

Subjects

Physics, Wavefront, Nuclear and High Energy Physics, Physics and Astronomy (miscellaneous), 010308 nuclear & particles physics, Holography, Surfaces and Interfaces, Plasma, Curvature, Plasma oscillation, 01 natural sciences, Ciências Naturais::Ciências Físicas [Domínio/Área Científica], law.invention, Computational physics, Amplitude, law, Physics::Plasma Physics, Frequency domain, 0103 physical sciences, Cluster (physics), lcsh:QC770-798, Physics::Accelerator Physics, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, 010306 general physics, QC

Abstract

We report the first comprehensive study of large amplitude Langmuir waves in a plasma of nanometer-scale clusters. Using an oblique angle single-shot frequency domain holography diagnostic, the shape of these wakefields is captured for the first time. The wavefronts are observed to curve backwards, in contrast to the forwards curvature of wakefields in uniform plasma. Due to the expansion of the clusters, the first wakefield period is longer than those trailing it. The features of the data are well described by fully relativistic two-dimensional particle-in-cell simulations and by a quasianalytic solution for a one- dimensional, nonlinear wakefield in a cluster plasma. info:eu-repo/semantics/publishedVersion

10. Channel optimization of high-intensity laser beams in millimeter-scale plasmas

Author

S. Zhang, Hideaki Habara, Luke Ceurvorst, Kazuo Tanaka, A. F. Savin, Naren Ratan, Mingsheng Wei, Muhammad Kasim, W. Theobald, Peter Norreys, James Sadler, Dustin Froula, and S. T. Ivancic

Subjects

Physics, High intensity, Plasma, Laser, 01 natural sciences, Omega, 010305 fluids & plasmas, law.invention, law, 0103 physical sciences, Millimeter, Atomic physics, 010306 general physics, Laser beams

Abstract

Channeling experiments were performed at the OMEGA EP facility using relativistic intensity ($g{10}^{18}\phantom{\rule{0.28em}{0ex}}{\mathrm{W}/\mathrm{cm}}^{2}$) kilojoule laser pulses through large density scale length ($\ensuremath{\sim}390--570 \ensuremath{\mu}\mathrm{m}$) laser-produced plasmas, demonstrating the effects of the pulse's focal location and intensity as well as the plasma's temperature on the resulting channel formation. The results show deeper channeling when focused into hot plasmas and at lower densities, as expected. However, contrary to previous large-scale particle-in-cell studies, the results also indicate deeper penetration by short (10 ps), intense pulses compared to their longer-duration equivalents. This new observation has many implications for future laser-plasma research in the relativistic regime.