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1. Impact of extended preplasma on energy coupling in kilojoule energy relativistic laser interaction with cone wire targets relevant to fast ignition

Author

T Yabuuchi, R Mishra, C McGuffey, B Qiao, M S Wei, H Sawada, Y Sentoku, T Ma, D P Higginson, K U Akli, D Batani, H Chen, L A Gizzi, M H Key, A J Mackinnon, H S McLean, P A Norreys, P K Patel, R B Stephens, Y Ping, W Theobald, C Stoeckl, and F N Beg

Subjects
Science, Physics, QC1-999
Abstract

Cone-guided fast ignition laser fusion depends critically on details of the interaction of an intense laser pulse with the inside tip of a cone. Generation of relativistic electrons in the laser plasma interaction (LPI) with a gold cone and their subsequent transport into a copper wire have been studied using a kJ-class intense laser pulse, OMEGA EP (850 J, 10 ps). We observed that the laser-pulse-energy-normalized copper K α signal from the Cu wire attached to the Au cone is significantly reduced (by a factor of 5) as compared to that from identical targets using the Titan laser (150 J, 0.7 ps) with 60 × less energy in the prepulse. We conclude that the decreased coupling is due to increased prepulse energy rather than 10 ps pulse duration, for which this effect has not been previously explored. The collisional particle-in-cell code PICLS demonstrates that the preformed plasma has a significant impact on generation of electrons and their transport. In particular, a longer scale length preplasma significantly reduces the energy coupling from the intense laser to the wire due to the larger offset distance between the relativistic critical density surface and the cone tip as well as a wider divergence of source electrons. We also observed that laser-driven plasma ionization increase in the LPI region can potentially alter the electron density profile during the laser interaction, forcing the electron source to be moved farther away from the cone tip which contributes to the reduction of energy coupling.

Published
2013
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2. Visualizing fast electron energy transport into laser-compressed high-density fast-ignition targets

Author

T. Iwawaki, F. J. Marshall, W. Theobald, Harry McLean, A. A. Solodov, Vladimir Glebov, Riccardo Betti, H. Chen, Christopher McGuffey, J. A. Delettrez, Farhat Beg, P. K. Patel, Mingsheng Wei, Hiroshi Sawada, Chad Mileham, R.W. Luo, Tilo Döppner, Bin Qiao, Richard B. Stephens, Leonard Jarrott, Hideaki Habara, Christian Stoeckl, M. H. Key, Joao Santos, E. M. Giraldez, and Toshinori Yabuuchi

Subjects
Physics, Imagination, business.industry, media_common.quotation_subject, General Physics and Astronomy, Nanotechnology, Plasma, Electron, Laser, 01 natural sciences, 010305 fluids & plasmas, Visualization, law.invention, Ignition system, Optics, Physics::Plasma Physics, law, 0103 physical sciences, Relativistic electron beam, Physics::Chemical Physics, 010306 general physics, business, Inertial confinement fusion, media_common
Abstract

Fast-ignition laser fusion involves directing an intense relativistic electron beam onto a fuel target. Experiments and simulations now enable a visualization of the location of fast electrons and the energy-coupling mechanisms at play.

Published
2016

3. Observation of extremely strong shock waves in solids launched by petawatt laser heating

Author

James Green, L. D. Van Woerkom, J. King, Andrew MacPhee, Peter Hakel, Sophia Chen, A. J. Mackinnon, R. Kodama, Alexander Robinson, Richard B. Stephens, Motoaki Nakatsutsumi, Hirotaka Nakamura, John Pasley, F. N. Beg, Tammy Ma, Hideaki Habara, Peter Norreys, Richard R. Freeman, K. Highbarger, M. H. Key, Kate Lancaster, R. L. Daskalova, Karl Krushelnick, and Paul A. Jaanimagi

Subjects
Physics, Shock wave, business.industry, Curved mirror, Electron, Condensed Matter Physics, Laser, 01 natural sciences, Collimated light, 010305 fluids & plasmas, law.invention, Ignition system, Optics, Physics::Plasma Physics, law, Extreme ultraviolet, 0103 physical sciences, Plasma diagnostics, Astrophysics::Earth and Planetary Astrophysics, 010306 general physics, business
Abstract

Understanding hydrodynamic phenomena driven by fast electron heating is important for a range of applications including fast electron collimation schemes for fast ignition and the production and study of hot, dense matter. In this work, detailed numerical simulations modelling the heating, hydrodynamic evolution, and extreme ultra-violet (XUV) emission in combination with experimental XUV images indicate shock waves of exceptional strength (200 Mbar) launched due to rapid heating of materials via a petawatt laser. We discuss in detail the production of synthetic XUV images and how they assist us in interpreting experimental XUV images captured at 256 eV using a multi-layer spherical mirror.

Published
2018

4. Applications and results of X-ray spectroscopy in implosion experiments on the National Ignition Facility

Author

Gilbert Collins, T. Ma, M. H. Key, A. J. Mackinnon, A. V. Hamza, Nobuhiko Izumi, Roberto Mancini, J. D. Kilkenny, Tilo Döppner, O. S. Jones, Joseph Ralph, Debra Callahan, Otto Landen, M. A. Barrios, Reuben Epstein, L. J. Suter, D. K. Bradley, David R. Farley, V. A. Smalyuk, D. D. Meyerhofer, H-S Park, P K Patel, S. H. Glenzer, Joseph J. MacFarlane, R. L. McCrory, B. A. Hammel, T. C. Sangster, C. J. Cerjan, S. M. Glenn, Bruce Remington, Howard A. Scott, Richard Town, Damien Hicks, K. B. Fournier, Nathan Meezan, G. A. Kyrala, Igor Golovkin, John Kline, S. N. Dixit, Susan Regan, J. L. Tucker, Melissa Edwards, A. Nikroo, and P. T. Springer

Subjects
Ignition system, Thermonuclear fusion, Hohlraum, Chemistry, law, Nuclear engineering, Implosion, Nuclear fusion, Nanotechnology, Plasma, National Ignition Facility, Inertial confinement fusion, law.invention
Abstract

Current inertial confinement fusion experiments on the National Ignition Facility (NIF) [G. H. Miller, E. I. Moses, and C. R. Wuest, Opt. Eng. 43, 2841 (2004)] are attempting to demonstrate thermonuclear ignition using x-ray drive by imploding spherical targets containing hydrogen-isotope fuel in the form of a thin cryogenic layer surrounding a central volume of fuel vapor [J. Lindl, Phys. Plasmas 2, 3933 (1995)]. The fuel is contained within a plastic ablator layer with small concentrations of one or more mid-Z elements, e.g., Ge or Cu. The capsule implodes, driven by intense x-ray emission from the inner surface of a hohlraum enclosure irradiated by the NIF laser, and fusion reactions occur in the central hot spot near the time of peak compression. Ignition will occur if the hot spot within the compressed fuel layer attains a high-enough areal density to retain enough of the reaction product energy to reach nuclear reaction temperatures within the inertial hydrodynamic disassembly time of the fuel mass ...

Published
2017

6. AN ANALYTIC MODEL FOR LASER-DRIVEN ABLATIVE IMPLOSION OF SPHERICAL-SHELL TARGETS

Author

Boye Ahlborn, A. R. Bell, and M. H. Key

Subjects
Physics, Computer simulation, business.industry, Plasma parameters, General Engineering, Implosion, Mechanics, Plasma, Laser, Spherical shell, law.invention, Optics, Physics::Plasma Physics, law, Laser power scaling, business, Scaling
Abstract

A simple analytic model is developed to describe the plasma parameters produced at peak compression when gas‐filled spherical shell targets are imploded by the ablation pressure produced by irradiation with constant laser power. The range of validity of the model is discussed and, in particular, the constraints due to preheating by hot electrons. Comparison with numerical simulation verifies the accuracy of the model. The implications of the scaling of compressed plasma parameters with target and laser parameters are discussed.

Published
2016

7. Hot surface ionic line emission and cold K-inner shell emission from petawatt-laser-irradiated Cu foil targets

Author

Hiroshi Sawada, Chad Mileham, Gianluca Gregori, Jaroslav Kuba, H.-S. Park, James Green, A. J. Mackinnon, Richard B. Stephens, T. C. Sangster, R. A. Snavely, Ronnie Shepherd, B. Zhang, Robert Clarke, Nobuhiko Izumi, P. K. Patel, J.F. Myatt, M. H. Key, Kramer Akli, Christian Stoeckl, John Pasley, Richard R. Freeman, Kate Lancaster, D. Neely, J. A. Koch, M. Storm, Siegfried Glenzer, J. A. King, W. Theobald, J. A. Delettrez, Sean Regan, Peter Norreys, and R. Heathcote

Subjects
Physics, Range (particle radiation), Electron shell, Electronic structure, Plasma, Electron, Condensed Matter Physics, Laser, Spectral line, law.invention, law, Electron temperature, Atomic physics
Abstract

A hot, 2 to 3 keV electron temperature surface plasma was observed in the interaction of a 0.7 ps petawatt laser beam with solid copper-foil targets at intensities > 10(20) W/cm(2). Copper K-shell spectra were measured in the range of 8 to 9 keV using a single-photon-counting x-ray charged-coupled-device camera. In addition to K-alpha and K-beta inner-shell lines, the emission contained the Cu He-alpha and Ly(alpha) lines, allowing the temperature to be inferred. These lines have not been observed previously with ultrafast laser pulses. For intensities less than 3 x 10(18) W/cm(2), only the K-alpha and K-beta inner-shell emissions are detected. Measurements of the absolute K-alpha yield as a function of the laser intensity are in general agreement with a model that includes refluxing and confinement of the suprathermal electrons in the target volume. (c) 2006 American Institute of Physics.

Published
2016

8. Imaging of high harmonic radiation emitted during the interaction of a 20 TW laser with a solid target

Author

A Dyson, M. H. Key, S.G. Preston, Peter Norreys, D. Neely, D.M. Chambers, Justin Wark, M. Castro-Colin, Matthew Zepf, and A. E. Dangor

Subjects
Physics, Brightness, business.industry, Astrophysics::High Energy Astrophysical Phenomena, General Physics and Astronomy, Radiation, Laser, law.invention, Wavelength, Optics, law, Extreme ultraviolet, Harmonic, High harmonic generation, business, Beam (structure)
Abstract

We present images of the source of extreme ultraviolet (XUV) harmonic emission at a wavelength of 220 Å from the interaction of a 20 TW, 1.053 μm Nd:glass laser beam focused to intensities up to 4X10 W cm-2 onto a solid target. From these measurements we determine an upper limit to the source size and brightness of the harmonic emission to show its efficacy as a novel source of short-pulse, coherent XUV radiation. We also demonstrate the empirical scaling of the harmonic generation efficiency with irradiance up to 10 W μm cm-2, and extrapolate to estimate the possible source brightness at higher irradiances. These source brightnesses are compared to those available from an x-ray laser system. © 1997 American Institute of Physics.

Published
2016

9. Operation of a single-photon-counting x-ray charge-coupled device camera spectrometer in a petawatt environment

Author

B. Zhang, M. H. Key, Stefan Karsch, Christian Stoeckl, R. J. Clarke, T. C. Sangster, Peter Norreys, P. K. Patel, and W. Theobald

Subjects
Physics, Photon, Pixel, Spectrometer, business.industry, Physics::Instrumentation and Detectors, Bolometer, Charge coupled device camera, Laser, Photon counting, law.invention, Optics, law, Electromagnetic shielding, Optoelectronics, business, Instrumentation
Abstract

The use of a single-photon-counting x-ray charge-coupled device (CCD) camera as an x-ray spectrometer is a well-established technique in ultrashort-pulse laser experiments. In single-photon-counting mode, the pixel value of each readout pixel is proportional to the energy deposited from the incident x-ray photon. For photons below 100 keV, a significant fraction of the events deposits all the energy in a single pixel. A histogram of the pixel readout values gives a good approximation of the x-ray spectrum. This technique requires almost no alignment, but it is very sensitive to signal-to-background issues, especially in a high-energy petawatt environment. Shielding the direct line of sight to the target was not sufficient to obtain a high-quality spectrum, for the experiments reported here the CCD camera had to be shielded from all sides with up to 10 cm of lead. © 2004 American Institute of Physics.

Published
2016

10. Measurements of fast electron scaling generated by petawatt laser systems

Author

R. G. Evans, Robbie Scott, Motoaki Nakatsutsumi, Tammy Ma, M. H. Key, Richard B. Stephens, K. L. Lancaster, Farhat Beg, J. King, Hiroshi Azechi, Takayoshi Norimatsu, R. Kodama, T. Yabuuchi, Peter Norreys, P. M. Nilson, James Green, Matthew Zepf, M. G. Haines, Mingsheng Wei, K. Takeda, Satyabrata Kar, T. Tanimoto, João Valente, Keiji Nagai, Kazuo Tanaka, H. Habara, J. R. Davies, and Mark Sherlock

Subjects
Chirped pulse amplification, Physics, Range (particle radiation), Spectrometer, business.industry, Pulse duration, Electron, Condensed Matter Physics, Laser, Potential energy, law.invention, Optics, law, Irradiation, business
Abstract

Fast electron energy spectra have been measured for a range of intensities between 1018 and 1021 W cm-2 and for different target materials using electron spectrometers. Several experimental campaigns were conducted on petawatt laser facilities at the Rutherford Appleton Laboratory and Osaka University, where the pulse duration was varied from 0.5 to 5 ps relevant to upcoming fast ignition integral experiments. The incident angle was also changed from normal incidence to 40° in p -polarized. The results confirm a reduction from the ponderomotive potential energy on fast electrons at the higher intensities under the wide range of different irradiation conditions. © 2009 American Institute of Physics.

Published
2016

11. Extreme ultraviolet probing of laser imprint in a thin foil using an x-ray laser backlighter

Author

Andrew MacPhee, M. H. Key, N.S. Kim, J. Warwick, Justin Wark, J. P. Knauer, S. G. Glendinning, Franz A. Weber, S. V. Weber, Jie Zhang, G.J. Tallents, L. B. Da Silva, E. Wolfrum, Arif Demir, Daniel H. Kalantar, Ciaran Lewis, Jiunn-Yuan Lin, R. F. Smith, Bruce Remington, and D. Neely

Subjects
Physics, business.industry, Nova (laser), Laser, law.invention, X-ray laser, Optics, law, Extreme ultraviolet, Laser beam quality, business, Instrumentation, Inertial confinement fusion, FOIL method, Beam (structure)
Abstract

For direct drive inertial confinement fusion, a capsule is imploded by directly illuminating the surface with laser light. Beam smoothing and uniformity of illumination affect the seeding of instabilities at the ablation front. We have developed a technique for studying the imprint of a laser beam on a thin foil using an x-ray laser as an extreme ultraviolet (XUV) backlighter. We use multilayer XUV optics to relay the x-ray laser onto the directly driven foil, and then to image the foil modulation onto a charged coupled device camera. This technique allows us to measure small fractional variations in the foil thickness. We have measured the modulation due to imprint from a low intensity 0.35 mu m drive beam incident on a 3 mu m Si foil using an yttrium x-ray laser on Nova. We present results from a similar technique to measure the imprinted modulation due to a low intensity 0.53 mu m drive beam incident on a 2 mu m Al foil using a germanium x-ray laser at the Vulcan facility. (C) 1997 American Institute of Physics.

Published
2016

12. Transport of energy by ultraintense laser-generated electrons in nail-wire targets

Author

K. Highbarger, Paul A. Jaanimagi, Mingsheng Wei, J. A. King, R. L. Daskalova, R. J. Mason, Scott Wilks, L. D. Van Woerkom, Tammy Ma, M. H. Key, S. P. Hatchett, Kate Lancaster, A. J. Mackinnon, Andrew MacPhee, Peter Norreys, Richard B. Stephens, W. Theobald, P. K. Patel, James Green, Kramer Akli, F. N. Beg, and Richard R. Freeman

Subjects
Physics, Relativistic plasma, law, Extreme ultraviolet, Magnetic trap, Electron temperature, Electron, Atomic physics, Condensed Matter Physics, Joule heating, Laser, Photon counting, law.invention
Abstract

Nail-wire targets (20 μm diameter copper wires with 80 μm hemispherical head) were used to investigate energy transport by relativistic fast electrons generated in intense laser-plasma interactions. The targets were irradiated using the 300 J, 1 ps, and 2 × 1020 W · cm-2 Vulcan laser at the Rutherford Appleton Laboratory. A spherically bent crystal imager, a highly ordered pyrolytic graphite spectrometer, and single photon counting charge-coupled device gave absolute Cu Kα measurements. Results show a concentration of energy deposition in the head and an approximately exponential fall-off along the wire with about 60 μm 1/e decay length due to resistive inhibition. The coupling efficiency to the wire was 3.3 ± 1.7% with an average hot electron temperature of 620 ± 125 keV. Extreme ultraviolet images (68 and 256 eV) indicate additional heating of a thin surface layer of the wire. Modeling using the hybrid E-PLAS code has been compared with the experimental data, showing evidence of resistive heating, magnetic trapping, and surface transport. © 2009 American Institute of Physics.

Published
2016

13. Characterization of a picosecond laser generated 4.5 keV Ti K -alpha source for pulsed radiography

Author

Richard R. Freeman, Thomas E. Cowan, P. K. Patel, S. P. Hatchett, Matthew Zepf, Christian Stoeckl, Marco Borghesi, C. D. Murphy, T. W. Phillips, Cliff Chen, M. H. Key, Kramer Akli, Kate Lancaster, Richard Town, Peter Norreys, Min Chen, J. A. Koch, A. J. Mackinnon, R. A. Snavely, Lorenzo Romagnani, Richard B. Stephens, J. A. King, and B. Zhang

Subjects
Physics, Brightness, Spectrometer, business.industry, Physics::Optics, Radiation, Laser, law.invention, Crystal, Optics, law, Ionization, K-alpha, Plasma diagnostics, Atomic physics, business, Instrumentation
Abstract

Kα radiation generated by interaction of an ultrashort (1 ps) laser with thin (25 μm) Ti foils at high intensity (2× 1016 W cm2) is analyzed using data from a spherical Bragg crystal imager and a single hit charge-coupled device spectrometer together with Monte Carlo simulations of Kα brightness. Laser to Kα and electron conversion efficiencies have been determined. We have also measured an effective crystal reflectivity of 3.75±2%. Comparison of imager data with data from the relatively broadband single hit spectrometer has revealed a reduction in crystal collection efficiency for high Kα yield. This is attributed to a shift in the K -shell spectrum due to Ti ionization. © 2005 American Institute of Physics.

Published
2016

14. Experimental characterization of a strongly coupled solid density plasma generated in a short-pulse laser target interaction

Author

R. I. Klein, M. H. Key, Gianluca Gregori, Ronnie Shepherd, H-S Park, R. Heathcote, A. J. Mackinnon, Siegfried Glenzer, Dmitri Ryutov, R. A. Snavely, B. Zhang, Scott Wilks, John Pasley, Nobuhiko Izumi, R. J. Clarke, Stephen J. Moon, P. K. Patel, Stephanie Hansen, Bruce Remington, N. Patel, and J A King

Subjects
Materials science, Electron, Plasma, Condensed Matter Physics, Laser, Spectral line, law.invention, Physics::Plasma Physics, law, Picosecond, Ionization, Electron temperature, Plasma diagnostics, Atomic physics
Abstract

We have measured high resolution copper Kα spectra from a picosecond high intensity laser produced plasma. By fitting the shape of the experimental spectra with a self-consistent-field model which includes all the relevant line shifts from multiply ionized atoms, we are able to infer time and spatially averaged electron temperatures (T e) and ionization state (Z) in the foil. Our results show increasing values for T e and Z when the overall mass of the target is reduced. In particular, we measure temperatures in excess of 200 eV with Z ∼ 13-14. For these conditions the ion-ion coupling constant is Γ ii ∼ 8-9, thus suggesting the achievement of a strongly coupled plasma regime. © 2005 WILEY-VCH Verlag GmbH and Co. KGaA, Weinheim.

Published
2016

15. Implosion and heating experiments of fast ignition targets by Gekko-XII and LFEX lasers

Author

Hiroaki Nishimura, M. Nakai, H. Kikuchi, K. Mima, H. Habara, Atsushi Sunahara, Tomoyuki Johzaki, T. Namimoto, K. Sawai, N. Miyanaga, Masakatsu Murakami, Hiroshi Azechi, Hitoshi Sakagami, H. Murakami, S. Matsuo, T. Iwawaki, T. Kawasaki, Nobuhiko Sarukura, John Pasley, Toshihiro Taguchi, Takao Nagai, K. Tsuji, Kazuo Tanaka, Ko. Kondo, H. Homma, Minoru Tanabe, Akifumi Iwamoto, Hideo Nagatomo, Yoichi Sakawa, Takahisa Jitsuno, Y. Fujimoto, T. Sogo, Keiichi Sueda, M. H. Key, O. Maegawa, Yoshiki Nakata, Zhe Zhang, T. Ozaki, Keisuke Shigemori, Shinsuke Fujioka, Y. Fujii, K. Shimada, Peter Norreys, Takayoshi Norimatsu, Y. Ishii, Kouji Tsubakimoto, R. Kodama, S. Ohira, Hirotaka Nakamura, Hiroyuki Shiraga, N. Morio, T. Kanabe, Takeshi Watari, H. Hosoda, Mayuko Koga, J. Kawanaka, Toshihiko Shimizu, and Yasunobu Arikawa

Subjects
Materials science, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Physics, QC1-999, Gamma ray, Implosion, Plasma, Astrophysics, Laser, law.invention, Ignition system, Optics, law, Neutron detection, Neutron, business, Beam (structure)
Abstract

The FIREX-1 project, the goal of which is to demonstrate fuel heating up to 5 keV by fast ignition scheme, has been carried out since 2003 including construction and tuning of LFEX laser and integrated experiments. Implosion and heating experiment of Fast Ignition targets have been performed since 2009 with Gekko-XII and LFEX lasers. A deuterated polystyrene shell target was imploded with the 0.53- μm Gekko-XII, and the 1.053- μm beam of the LFEX laser was injected through a gold cone attached to the shell to generate hot electrons to heat the imploded fuel plasma. Pulse contrast ratio of the LFEX beam was significantly improved. Also a variety of plasma diagnostic instruments were developed to be compatible with harsh environment of intense hard x-rays (γ rays) and electromagnetic pulses due to the intense LFEX beam on the target. Large background signals around the DD neutron signal in time-of-flight record of neutron detector were found to consist of neutrons via (γ,n) reactions and scattered gamma rays. Enhanced neutron yield was confirmed by carefully eliminating such backgrounds. Neutron enhancement up to 3.5 × 107 was observed. Heating efficiency was estimated to be 10-20% assuming a uniform temperature rise model. © Owned by the authors, published by EDP Sciences, 2013.

Published
2016

16. Proton radiography of a laser-driven implosion

Author

T. W. Phillips, H. Habara, A. Nikkro, S. P. Hatchett, D. Neely, Damien Hicks, Marco Borghesi, Lorenzo Romagnani, M. H. Key, Richard R. Freeman, M. M. Notley, Kate Lancaster, R. C. Clarke, Richard B. Stephens, P. K. Patel, Satyabrata Kar, Richard Town, A. J. Mackinnon, R. A. Snavely, J A King, D. S. Hey, and Peter Norreys

Subjects
Physics, Proton, business.industry, Monte Carlo method, General Physics and Astronomy, Pulse duration, Implosion, Physics and Astronomy(all), Laser, law.invention, Core (optical fiber), Wavelength, Optics, law, Physics::Plasma Physics, Physics::Accelerator Physics, Scattering theory, Atomic physics, business
Abstract

Protons accelerated by a picosecond laser pulse have been used to radiograph a 500μm diameter capsule, imploded with 300 J of laser light in 6 symmetrically incident beams of wavelength 1.054μm and pulse length 1 ns. Point projection proton backlighting was used to characterize the density gradients at discrete times through the implosion. Asymmetries were diagnosed both during the early and stagnation stages of the implosion. Comparison with analytic scattering theory and simple Monte Carlo simulations were consistent with a 3±1g/cm3 core with diameter 85±10μm. Scaling simulations show that protons >50MeV are required to diagnose asymmetry in ignition scale conditions. © 2006 The American Physical Society.

Published
2016

17. Diagnosing laser-driven, shock-heated foam target with Al absorption spectroscopy on OMEGA EP

Author

T. Yabuuchi, Scott Wilks, Farhat Beg, P. K. Patel, Mingsheng Wei, Hiroshi Sawada, K. M. Saito, Harry McLean, Richard B. Stephens, A. J. Mackinnon, Riccardo Betti, Susan Regan, K. S. Anderson, R. Paguio, J. Hund, and M. H. Key

Subjects
Shock wave, Nuclear and High Energy Physics, Radiation, Materials science, Absorption spectroscopy, Streak camera, Pulse duration, Electron, Plasma, Laser, law.invention, law, Electron temperature, Atomic physics
Abstract

Results on diagnoses of laser-driven, shock-heated foam plasma with time-resolved Al 1s-2p absorption spectroscopy are reported. Experiments were carried out to produce a platform for the study of relativistic electron transport. In cone-guided Fast Ignition (FI), relativistic electrons generated by a high-intensity, short-pulse igniter beam must be transported through a cone tip to an imploded core. Transport of the energetic electrons could be significantly affected by the temperature-dependent resistivity of background plasmas. The experiment was conducted using four UV beams of the OMEGA EP laser at the Laboratory For Laser Energetics. One UV beam (1.2 kJ, 3.5 ns square) was used to launch a shock wave into a foam package target, consisting of 200 mg/cm3 CH foam with aluminum dopant and a solid plastic container surrounding the foam layer. The other three UV beams with the total energy of 3.2 kJ in 2.5 ns pulse duration were tightly focused onto a Sm dot target to produce a point X-ray source in the energy range of 1.4–1.6 keV. The quasi-continuous X ray signal was transmitted through the shock-heated Al-doped, foam layer and recorded with an X-ray streak camera. The measured 1s-2p Al absorption features were analyzed using an atomic physics code FLYCHK. Electron temperature of 40 eV inferred from the spectral analysis is consistent with 2-D DRACO Radiation-hydrodynamic simulations.

Published
2012

18. Present states and future prospect of fast ignition realization experiment (FIREX) with Gekko and LFEX Lasers at ILE

Author

Atsushi Sunahara, O. Motojima, Akifumi Iwamoto, Yasushi Fujimoto, Tomoyuki Johzaki, Mitsutaka Isobe, Keisuke Shigemori, Yasunobu Arikawa, Shinsuke Fujioka, Hong-bo Cai, Ryosuke Kodama, K. A. Tanaka, Hiroshi Azechi, H. Homma, M. H. Key, Hideaki Takabe, J. Kawanaka, Yasuyuki Nakao, K. Mima, H. Habara, Mayuko Koga, N. Miyanaga, Yoshiki Nakata, Toshihiko Shimizu, Toshiyuki Mito, Hiroaki Nishimura, Hideo Nagatomo, T. Tsubakimoto, Nobuhiko Sarukura, Mitsuo Nakai, Hirotaka Nakamura, Hiroyuki Shiraga, T. Ozaki, Peter Norreys, Takayoshi Norimatsu, Takahisa Jitsuno, Toshihiro Taguchi, Y. Hironaka, H. Hosoda, Takeshi Watari, T. Tanimoto, John Pasley, Yoichi Sakawa, Hitoshi Sakagami, Minoru Tanabe, and M. Murakami

Subjects
Physics, Nuclear and High Energy Physics, business.industry, Short pulse laser, Implosion, Laser, law.invention, Pulse (physics), Ignition system, Optics, law, Coupling efficiency, business, Instrumentation, Realization (systems), Pulse-width modulation
Abstract

The fast ignition realization experiment (FIREX) project is progressing. The new short pulse laser system, LFEX laser, has been completely assembled and one of the four beamlets is now in operation. A fast-ignition experiment was performed using this single short pulse combined with the Gekko XII implosion laser. The energy of the GXII implosion laser was about 2 kJ and the pulse width was 1.5 ns. The energy of the LFEX laser was increased upto 800 J and two pulse durations 5 and 1.6 ps were compared. Targets were deuterated plastic shells with gold cones. It was found that the neutron yield was increased by a factor of 30 as a result of the fast electron-induced heating in LFEX 1.6 ps shot. The estimated coupling efficiency between the LFEX laser pulse and the compressed fuel was low (less than 5%). This may be due to pre-plasma formed by light arriving at the target before the main laser pulse. Further investigations and attempts to overcome these problems are now in progress. © 2011 Elsevier B.V.

Published
2011

19. Surface heating of wire plasmas using laser-irradiated cone geometries

Author

R. Heathcote, Motonobu Tampo, K. Krushelnick, M. H. Key, Hirotaka Nakamura, James Green, D. Hey, Peter Norreys, Nigel Woolsey, Hideaki Habara, Kate Lancaster, Ryosuke Kodama, Motoaki Nakatsutsumi, Richard B. Stephens, L. D. Van Woerkom, Farhat Beg, Mingsheng Wei, K. Highbarger, Ian Musgrave, M. Storm, Wolfgang Theobald, Kramer Akli, S. J. Hawkes, David C. Clark, N. Patel, Sophia Chen, Cristina Hernandez-Gomez, Richard R. Freeman, R. L. Weber, and Christopher D. Gregory

Subjects
Physics, business.industry, General Physics and Astronomy, Plasma, Laser, Magnetic field, law.invention, Interferometry, Optics, law, State of matter, business, Joule heating, National Ignition Facility, Laser Mégajoule
Abstract

Petawatt lasers can generate extreme states of matter, making them unique tools for high-energy-density physics. Pressures in the gigabar regime can potentially be generated with cone-wire targets when the coupling efficiency is high and temperatures reach 2–4 keV (ref. 1). The only other method of obtaining such gigantic pressures is to use the megajoule laser facilities being constructed (National Ignition Facility and Laser MegaJoule). The energy can be transported over surprisingly long distances but, until now, the guiding mechanism has remained unclear. Here, we present the first definitive experimental proof that the heating is maximized close to the wire surface, by comparison of interferometric measurements with hydrodynamic simulations. New hybrid particle-in-cell simulations show the complex field structures for the first time, including a reversal of the magnetic field on the inside of the wire. This increases the return current in a spatially separated thin layer below the wire surface, resulting in the enhanced level of ohmic heating. There are a significant number of applications in high-energy-density science, ranging from equation-of-state studies to bright, hard X-ray sources, that will benefit from this new understanding of energy transport.

Published
2007

20. MeV proton generation and efficiency from an intense laser irradiated foil

Author

Barbara F. Lasinski, A. J. Mackinnon, P. K. Patel, S. P. Hatchett, Scott Wilks, Max Tabak, Mark Foord, M. H. Key, and Richard Town

Subjects
Nuclear and High Energy Physics, Radiation, Materials science, Proton, law, Physics::Accelerator Physics, Irradiation, Atomic physics, Warm dense matter, Laser, Proton energy, FOIL method, law.invention
Abstract

The proton energy distribution generated from the interaction of an intense ( Iλ 2 ≈ 10 20 W/cm 2 μm 2 ) short-pulse (100 fs) laser with a thin foil is investigated using energy resolved measurements and 2D collisional PIC-hybrid simulations. The measured absolute proton spectrum is well matched by a 1.7 MeV exponential function for energies

Published
2007

21. Proton Fast Ignition

Author

S. P. Hatchett, A. J. Mackinnon, M. H. Key, P. K. Patel, Richard B. Stephens, R. Snavely, and Richard R. Freeman

Subjects
Physics, Nuclear and High Energy Physics, Proton, 020209 energy, Mechanical Engineering, Plasma jet, Physics::Optics, 02 engineering and technology, 01 natural sciences, 010305 fluids & plasmas, law.invention, Ignition system, Nuclear physics, Nuclear Energy and Engineering, Physics::Plasma Physics, law, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Physics::Accelerator Physics, General Materials Science, Physics::Atomic Physics, Physics::Chemical Physics, Atomic physics, Beam (structure), Civil and Structural Engineering
Abstract

Fast ignition by a laser-generated, ballistically focused proton plasma jet is a more recently proposed alternative to the original concept of fast ignition by a laser-generated beam of relativisti...

Published
2006

22. Simulations of electron transport for fast ignition using LSP

Author

M. H. Key, Richard Town, Dale Welch, L.A. Cottrill, R. A. Snavely, Barbara F. Lasinski, A. B. Langdon, William L. Kruer, Cliff Chen, Charles H. Still, Scott Wilks, and Max Tabak

Subjects
Physics, Nuclear and High Energy Physics, Radius, Electron, Fusion power, Laser, Electron transport chain, law.invention, Pulse (physics), Ignition system, law, Atomic physics, Instrumentation, Beam (structure)
Abstract

A crucial issue for the viability of the fast ignition approach to inertial fusion energy is the transport of the ignition pulse energy from the critical surface to the high-density compressed fuel. Experiments have characterized this transport through the interaction of short pulse, high intensity lasers with solid-density targets containing thin Kα fluorescence layers. These experiments show a reasonably well-collimated beam, although with a significantly larger radius than the incident laser beam. We report on LSP calculations of these experiments, which show reasonable agreement with the experimental observations.

Published
2005

23. An overview of LLNL high-energy short-pulse technology for advanced radiography of laser fusion experiments

Author

Mary L. Spaeth, J.A. Britten, Edward I. Moses, Scott C. Mitchell, William A. Molander, Deanna Marie Pennington, Kenneth M. Skulina, S J Bryan, G. Beer, John K. Crane, T C Carlson, Jay W. Dawson, Benoit Wattellier, John A. Caird, David N. Fittinghoff, Brent C. Stuart, Michael C. Rushford, Curly R. Hoaglan, Alvin C. Erlandson, Mark R. Hermann, G. L. Tietbohl, L. Jones, M. H. Key, Christopher P. J. Barty, Otto Landen, Igor Jovanovic, A. Iyer, Curtis G. Brown, A.M. Komashko, H. Nguyen, L. Risinger, S.A. Payne, J D Nissen, Raymond J. Beach, Norman D. Nielsen, and Z. Liao

Subjects
Physics, Chirped pulse amplification, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, business.industry, Condensed Matter Physics, IGNITOR, Laser, law.invention, Optics, Physics::Plasma Physics, law, Industrial radiography, Picosecond, Physics::Accelerator Physics, business, National Ignition Facility, Inertial confinement fusion, Ultrashort pulse
Abstract

The technical challenges and motivations for high-energy, short-pulse generation with the National Ignition Facility (NIF) and possibly other large-scale Nd : glass lasers are reviewed. High-energy short-pulse generation (multi-kilojoule, picosecond pulses) will be possible via the adaptation of chirped pulse amplification laser techniques on NIF. Development of metre-scale, high-efficiency, high-damage-threshold final optics is a key technical challenge. In addition, deployment of high energy petawatt (HEPW) pulses on NIF is constrained by existing laser infrastructure and requires new, compact compressor designs and short-pulse, fibre-based, seed-laser systems. The key motivations for HEPW pulses on NIF is briefly outlined and includes high-energy, x-ray radiography, proton beam radiography, proton isochoric heating and tests of the fast ignitor concept for inertial confinement fusion.

Published
2004

24. Characterization of 7Li(p,n)7Be neutron yields from laser produced ion beams for fast neutron radiography

Author

Mingsheng Wei, Edward B. Clark, M. H. Key, Kenneth W. D. Ledingham, Kate Lancaster, S. Karsch, C. D. Murphy, Peter Norreys, R. R. Freeman, Christian Stoeckl, Karl Krushelnick, H. Habara, Yusuke Toyama, Paul McKenna, R. Kodama, J A King, Farhat Beg, Matthew Zepf, and Richard B. Stephens

Subjects
Physics, Bonner sphere, Neutron imaging, Neutron stimulated emission computed tomography, Neutron scattering, Condensed Matter Physics, Laser, law.invention, law, Neutron cross section, Neutron source, Neutron, Atomic physics, QC
Abstract

Investigations of 7Li(p,n)7Be reactions using Cu and CH primary and LiF secondary targets were performed using the VULCAN laser [C.N. Danson et al., J. Mod. Opt. 45, 1653 (1997)] with intensities up to 3×1019 W cm−2. The neutron yield was measured using CR-39 plastic track detector and the yield was up to 3×108 sr−1 for CH primary targets and up to 2×108 sr−1 for Cu primary targets. The angular distribution of neutrons was measured at various angles and revealed a relatively anisotropic neutron distribution over 180° that was greater than the error of measurement. It may be possible to exploit such reactions on high repetition, table-top lasers for neutron radiography.

Published
2004

25. Integrated implosion/heating studies for advanced fast ignition

Author

M. H. R. Hutchinson, D. Neely, C. Hemandez-Gomez, J. A. King, S. J. Hawkes, Kazuo Tanaka, John Collier, Richard B. Stephens, B. Zhang, Richard R. Freeman, Ryosuke Kodama, Matthew Zepf, R. Heathcote, Christian Stoeckl, M. H. Key, Kate Lancaster, A. J. Mackinnon, R. A. Snavely, Roger Evans, Marco Borghesi, Takayoshi Norimatsu, Lorenzo Romagnani, Kramer Akli, Yusuke Toyama, Hideaki Habara, Peter Norreys, Stefan Karsch, Robert Clarke, P. K. Patel, S. P. Hatchett, A. Nikroo, and C. D. Murphy

Subjects
Physics, Opacity, business.industry, chemistry.chemical_element, Implosion, Plasma, Nanosecond, Condensed Matter Physics, Laser, Neodymium, law.invention, Optics, chemistry, law, Plasma diagnostics, Atomic physics, business, Inertial confinement fusion
Abstract

Integrated experiments to investigate the ultrafast heating of implosions using cone/shell geometries have been performed at the Rutherford Appleton Laboratory. The experiments used the 1054 nm, nanosecond, 0.9 kJ output of the VULCAN Nd:glass laser to drive 486 μm diameter, 6 μm wall thickness Cu-doped deuterated plastic (CD) shells in 6-beam cubic symmetry. Measurements of the opacity of the compressed plasma using two-dimensional spatially resolved Ti-Kα x-ray radiography suggest that densities of 4 g cm−3 and areal densities of 40 mg cm−2 were achieved at stagnation. Upper limits on the heating with both 1 ps and 10 ps pulses were deduced from the fluorescent yield from the Cu dopant. The data suggest that control of the preformed plasma scale-length inside the cone is necessary for efficient coupling to the compressed plasma.

Published
2004

26. Understanding the role of fast electrons in the heating of dense matter: experimental techniques and recent results

Author

C. Anderson, R. R. Freeman, M. H. Key, J. M. Hill, Richard B. Stephens, Thomas E. Cowan, A. J. Mackinnon, S. P. Hatchett, J A King, Jeffrey A. Koch, and R. Snavely

Subjects
Physics, Radiation, Traverse, Isochoric process, Computation, Electron, Plasma, Laser, Electron transport chain, Atomic and Molecular Physics, and Optics, law.invention, law, Current (fluid), Atomic physics, Spectroscopy
Abstract

An intense laser impinging upon dense matter converts a large fraction of its energy into fast electrons. (Here we take “fast” to mean electrons that are much more energetic than the normal Boltzmann-like distribution measured in the tens to hundreds of eV.) Upon transiting the interior of the dense matter, these electrons are responsible for isochoric heating of the material. Just how these electrons traverse the material, and various interfaces within the material, is a subject of substantial amounts of computation and theory, and recently, experiments. Here we outline the nature of the heating mechanisms, and the current level of understanding of the complex physical processes. In particular we discuss new experimental techniques to record essential features of this transport problem.

Published
2003

27. High-intensity lasers and controlled fusion

Author

A. J. Mackinnon, R. Snavely, J. M. Hill, J A King, Jeffrey A. Koch, M. H. Key, Richard B. Stephens, R. R. Freeman, S. P. Hatchett, C. Anderson, and Thomas E. Cowan

Subjects
Physics, Fusion, Field (physics), Optical physics, Plasma, IGNITOR, Laser, Engineering physics, Atomic and Molecular Physics, and Optics, law.invention, Nuclear physics, Ignition system, Physics::Plasma Physics, law, Inertial confinement fusion
Abstract

The use of high-intensity lasers to cause ignition in inertial confinement fusion is presented, with emphasis on current experimental programs and physical concepts that are at the forefront of the field. In particular, we highlight the issues of fast electron transport through dense materials, an essential element of the “Fast Ignitor” concept.

Published
2003

28. 4.5- and 8-keV emission and absorption x-ray imaging using spherically bent quartz 203 and 211 crystals (invited)

Author

J. F. Seely, Thomas E. Cowan, S. P. Hatchett, Richard B. Stephens, Charles M. Brown, Yefim Aglitskiy, J. A. Koch, M. H. Key, Glenn E. Holland, Richard R. Freeman, A. J. Mackinnon, and R. A. Snavely

Subjects
Diffraction, Materials science, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Bent molecular geometry, X-ray, Laser, law.invention, Optics, law, Plasma diagnostics, Monochromatic color, business, Absorption (electromagnetic radiation), Instrumentation, Quartz
Abstract

We have used spherically-bent quartz 203 and 211 crystals to image 4.5- and 8-keV sources in both emission and absorption geometries. These imaging systems are straightforward to align, provide high throughput, and can provide high spatial resolution over large fields of view. We discuss the imaging geometry and alignment strategies, and we present experimental results we have obtained from a 1-ns-duration, multikilojoule laser facility and from sub-ps-duration, ultrahigh-intensity laser facilities. Our successful applications suggest that high-quality, spherically-bent quartz crystals may be used to image at many different x-ray energies due to the numerous diffraction planes available from quartz. This range of usable x-ray energies increases the number of applications that might benefit from high-resolution, high-brightness, monochromatic x-ray imaging using bent crystals.

Published
2003

29. Fast electron transport and heating in solid-density matter

Author

R. R. Freeman, T. E. Cowan, E. Martinolli, A. J. Mackinnon, Dimitri Batani, M. Koenig, M. H. Key, E. Perelli-Cippo, F. Scianitti, M. Rabec Le Gloahec, C. Andersen, Sophie Baton, Joao Santos, R. Snavely, J. A. King, François Amiranoff, Todd H. Hall, Richard B. Stephens, and Christophe Rousseaux

Subjects
Physics, X-ray spectroscopy, Spectrometer, Cathode ray, Context (language use), Alpha particle, Electron, Electrical and Electronic Engineering, Atomic physics, Condensed Matter Physics, IGNITOR, Inertial confinement fusion, Atomic and Molecular Physics, and Optics
Abstract

Two experiments have been performed to investigate heating by high-intensity laser-generated electrons, in the context of studies of the fast ignitor approach to inertial confinement fusion (ICF). A new spectrometer and layered targets have been used to detect Kα emission from aluminum heated by a fast electron beam. Results show that a temperature of about 40 eV is reached in solid density aluminum up to a depth of about 100 μm.

Published
2002

30. Propagation issues and energetic particle production in laser–plasma interactions at intensities exceeding 1019 W/cm2

Author

Marco Galimberti, L. A. Gizzi, A. J. Mackinnon, Marco Borghesi, M. H. Key, Angelo Schiavi, O. Willi, R.D. Snavely, W. Nazarov, S. P. Hatchett, D. H. Campbell, and P. K. Patel

Subjects
Physics, Proton, Plasma, Condensed Matter Physics, Laser, Atomic and Molecular Physics, and Optics, Collimated light, law.invention, Relativistic plasma, law, Particle, Plasma channel, Electrical and Electronic Engineering, Atomic physics, Inertial confinement fusion
Abstract

A series of experiments recently carried out at the Rutherford Appleton Laboratory investigated various aspects of the laser–plasma interaction in the relativistic intensity regime. The propagation of laser pulses through preformed plasmas was studied at intensities exceeding 1019 W/cm2. The transmission of laser energy through long-scale underdense plasmas showed to be inefficient unless a plasma channel is preformed ahead of the main laser pulse. The study of the interaction with overdense plasmas yielded indication of collimated energy transport through the plasma. The production of fast particles during the interaction with solid density targets was also investigated. The measurements revealed the presence of a small-sized directional source of multi-megaelectron volt protons, which was not observed when a plasma was preformed at the back of the solid target. The properties of the source are promising in view of its use in radiographic imaging of dense matter, and preliminary tests were carried out.

Published
2002

31. Transport and spatial energy deposition of relativistic electrons in copper-doped fast ignition plasmas

Author

Leonard Jarrott, M. H. Key, Farhat Beg, R.W. Luo, Hideaki Habara, C. McGuffey, J. A. Delettrez, H. Chen, E. M. Giraldez, J. J. Santos, Bin Qiao, P. K. Patel, T. Iwawaki, F. J. Marshall, W. Theobald, Mingsheng Wei, Hiroshi Sawada, Chad Mileham, V. Y. Glebov, Tilo Döppner, Riccardo Betti, Toshinori Yabuuchi, A. A. Solodov, Harry McLean, Richard B. Stephens, and Christian Stoeckl

Subjects
Physics, chemistry.chemical_element, Electron, Plasma, Condensed Matter Physics, Laser, 01 natural sciences, Copper, 010305 fluids & plasmas, law.invention, chemistry, law, 0103 physical sciences, Area density, Atomic physics, 010306 general physics, Inertial confinement fusion, Beam (structure), Laboratory for Laser Energetics
Abstract

Fast electron transport and spatial energy deposition are investigated in integrated cone-guided Fast Ignition experiments by measuring fast electron induced copper K-shell emission using a copper tracer added to deuterated plastic shells with a geometrically reentrant gold cone. Experiments were carried out at the Laboratory for Laser Energetics on the OMEGA/OMEGA-EP Laser where the plastic shells were imploded using 54 of the 60 OMEGA60 beams (3ω, 20 kJ), while the high intensity OMEGA-EP (BL2) beam (1 ω, 10 ps, 500 J, Ipeak > 1019 W/cm2) was focused onto the inner cone tip. A retrograde analysis using the hybrid-PIC electron transport code, ZUMA, is performed to examine the sensitivity of the copper Kα spatial profile on the laser-produced fast electrons, facilitating the optimization of new target point designs and laser configurations to improve the compressed core areal density by a factor of 4 and the fast electron energy coupling by a factor of 3.5.

Published
2017

32. Investigation of fast-electron-inducedKα x rays in laser-produced blow-off plasma

Author

Mingsheng Wei, Hiroshi Sawada, P. K. Patel, Alessio Morace, Harry McLean, Nobuhiko Nakanii, S. Chawla, M. H. Key, A. J. Mackinnon, Farhat Beg, Kramer Akli, R.B. Stephens, and Toshinori Yabuuchi

Subjects
Materials science, Spectrometer, law, X-ray, Plasma, Electron, Irradiation, Monochromatic color, Atomic physics, Laser, Beam (structure), law.invention
Abstract

Refluxing of fast electrons generated by high-intensity, short-pulse lasers was investigated by measuring electron-induced Kα x rays from a buried tracer layer. Using planar foils of Au/Cu/CH, the 150-J, 0.7-ps TITAN short-pulse laser was focused on the gold foil to generate fast electrons and the 3-ns, 300-J long pulse beam irradiated on the CH side to create expanding plasma as a conducting medium. By delaying the short-pulse beam timing from the long pulse laser irradiation, the plasma size was varied to change electron refluxing in the target rear. The total yields and two-dimensional images of 8.05-keV Cu-Kα x ray were recorded with an x-ray spectrometer and two monochromatic crystal imagers. The measurements show that the integrated yields decrease by a factor of 10 from refluxing to the nonrefluxing limit. Similar radial profiles of the Kα images in the rear were observed at all delays. Hybrid-particle-in-cell simulations using plasma profiles calculated by a radiation-hydrodynamic code HYDRA agree well with the measured Kα yields. The simulations suggest that conducting plasma with the size of ∼300 μm in the laser direction and ∼600 μm in the lateral direction at the density of 2 × 1020 1/cm3 is sufficiently large to prevent electrons from refluxing in the target. The parameters found in this study can be useful in designing experiments utilizing a Kα x-ray source in refluxing regime or a tracer layer in nonrefluxing regime.

Published
2014

33. A Concept Exploration Program in Fast Ignition Inertial Fusion — Final Report

Author

M. H. Key, Mingsheng Wei, Richarad Burnite Stephens, A. J. Mackinnon, Richard R. Freeman, and L. D. Van Woekom

Subjects
Scientific instrument, Engineering, Inertial frame of reference, business.industry, Electrical engineering, Fusion power, law.invention, Ignition system, Titan (supercomputer), law, Systems engineering, National laboratory, business, National Ignition Facility, Inertial confinement fusion
Abstract

The Fast Ignition (FI) approach to Inertial Confinement Fusion (ICF) holds particular promise for fusion energy because the independently generated compression and ignition pulses allow ignition with less compression, resulting in (potentially) higher gain. Exploiting this concept effectively requires an understanding of the transport of electrons in prototypical geometries and at relevant densities and temperatures. Our consortium, which included General Atomics (GA), The Ohio State University (OSU), the University of California, San Diego (UCSD), University of California, Davis (UC-Davis), and Princeton University under this grant (~$850K/yr) and Lawrence Livermore National Laboratory (LLNL) under a companion grant, won awards in 2000, renewed in 2005, to investigate the physics of electron injection and transport relevant to the FI concept, which is crucial to understand electron transport in integral FI targets. In the last two years we have also been preparing diagnostics and starting to extend the work to electron transport into hot targets. A complementary effort, the Advanced Concept Exploration (ACE) program for Fast Ignition, was funded starting in 2006 to integrate this understanding into ignition schemes specifically suitable for the initial fast ignition attempts on OMEGA and National Ignition Facility (NIF), and during that time these two programs have been managedmore » as a coordinated effort. This result of our 7+ years of effort has been substantial. Utilizing collaborations to access the most capable laser facilities around the world, we have developed an understanding that was summarized in a Fusion Science & Technology 2006, Special Issue on Fast Ignition. The author lists in the 20 articles in that issue are dominated by our group (we are first authors in four of them). Our group has published, or submitted 67 articles, including 1 in Nature, 2 Nature Physics, 10 Physical Review Letters, 8 Review of Scientific Instruments, and has been invited to give numerous talks at national and international conferences (including APS-DPP, IAEA, FIW). The advent of PW capabilities – at Rutherford Appleton Lab (UK) and then at Titan (LLNL) (2005 and 2006, respectively), was a major step toward experiments in ultra-high intensity high-energy FI relevant regime. The next step comes with the activation of OMEGA EP at LLE, followed shortly by NIF-ARC at LLNL. These capabilities allow production of hot dense material for electron transport studies. In this transitional period, considerable effort has been spent in developing the necessary tools and experiments for electron transport in hot and dense plasmas. In addition, substantial new data on electron generation and transport in metallic targets has been produced and analyzed. Progress in FI detailed in §2 is related to the Concept Exploration Program (CEP) objectives; this section is a summary of the publications and presentations listed in §5. This work has benefited from the synergy with work on related Department of Energy (DOE) grants, the Fusion Science Center and the Fast Ignition Advanced Concept Exploration grant, and from our interactions with overseas colleagues, primarily at Rutherford Appleton Laboratory in the UK, and the Institute for Laser Engineering in Japan.« less

Published
2014

34. Effect of defocusing on picosecond laser-coupling into gold cones

Author

Mark Sherlock, Hazel Lowe, Tammy Ma, M. H. Key, Alexander Thomas, Andrew MacPhee, Trevor Winstone, S. Sarfraz, M. M. Notley, Mingsheng Wei, Erik Wagenaars, I. Bush, R. J. Clarke, James Green, T. Yabuuchi, Wigen Nazarov, Richard B. Stephens, Alexander Robinson, L M R Gartside, A. J. Mackinnon, Christopher Spindloe, John Pasley, Farhat Beg, University of St Andrews. School of Chemistry, and University of St Andrews. EaSTCHEM

Subjects
Physics, business.industry, Density, Electron, Condensed Matter Physics, Laser, QD Chemistry, Ignition, Photon counting, law.invention, Plasma, Optics, QC Physics, Highly oriented pyrolytic graphite, law, Picosecond, Electron temperature, Plasma diagnostics, QD, Atomic physics, Gain, business, Fusion, Inertial confinement fusion, QC
Abstract

This work was supported in part by DTRA under Basic Research Award No. HDTRA1-10-10077. Here, we show that defocusing of the laser in the interaction of a picosecond duration, 1.053 μm wavelength, high energy pulse with a cone-wire target does not significantly affect the laser energy coupling efficiency, but does result in a drop in the fast electron effective temperature. This may be beneficial for fast ignition, since not only were more electrons with lower energies seen in the experiment but also the lower prepulse intensity will reduce the amount of preplasma present on arrival of the main pulse, reducing the distance the hot electrons have to travel. We used the Vulcan Petawatt Laser at the Rutherford Appleton Laboratory and gold cone targets with approximately 1 mm long, 40 μm diameter copper wires attached to their tip. Diagnostics included a quartz crystal imager, a pair of highly oriented pyrolytic graphite crystal spectrometers and a calibrated CCD operating in the single photon counting regime, all of which looked at the copper Kα emission from the wire. A short pulse optical probe, delayed 400 ps relative to the main pulse was employed to diagnose the extent of plasma expansion around the wire. A ray-tracing code modeled the change in intensity on the interior surface of the cone with laser defocusing. Using a model for the wire copper Kα emission coupled to a hybrid Vlasov-Fokker-Planck code, we ran a series of simulations, holding the total energy in electrons constant whilst varying the electron temperature, which support the experimental conclusions. Publisher PDF

Published
2014

35. Measurements of the XUV mass absorption coefficient of an overdense liquid metal

Author

Bruce Remington, P D S Burnett, M. H. Key, S. J. Rose, Ciaran Lewis, R. Keenan, A. Djaoui, Richard W. Lee, A M Machacek, Carlos A. Iglesias, R.M.N. O'Rourke, A. M. Allen, I. R. Al’Miev, Daniel H. Kalantar, Justin Wark, Troy W. Barbee, and E. Wolfrum

Subjects
Physics, Liquid metal, Extended X-ray absorption fine structure, Electron, Photon energy, Condensed Matter Physics, Laser, Atomic and Molecular Physics, and Optics, law.invention, law, Attenuation coefficient, Extreme ultraviolet, Mass attenuation coefficient, Atomic physics
Abstract

The increase in the XUV mass absorption coefficient of liquid aluminium, produced by high-power-laser shock-compression, is measured using XUV laser radiography. At a photon energy of 63 eV a change in the mass absorption coefficient by up to a factor of ~2.2 is determined at densities close to twice that of solid and electron temperatures of the order of 1 eV. Comparison with hydrodynamic simulations indicate that the absorption coefficient scales with density as ρ1.3±0.2.

Published
2001

36. A review of laser and synchrotron based X-ray sources

Author

M. H. Key and Roland Smith

Subjects
Free electron model, Physics, Brightness, business.industry, X-ray, General Physics and Astronomy, Synchrotron radiation, Laser, Synchrotron, law.invention, Laser technology, Optics, law, Extreme ultraviolet, Optoelectronics, business
Abstract

The rapid development of laser technology and related progress in research using lasers is shifting the boundaries where laser based sources are preferred over other light sources particularly in the XUV and x-ray spectral region. Laser based sources have exceptional capability for short pulse and high brightness and with improvements in high repetition rate pulsed operation, such sources are also becoming more interesting for their average power capability. This study presents an evaluation of the current capabilities and near term future potential of laser based light sources and summarises, for the purpose of comparison, the characteristics and near term prospects of sources based on synchrotron radiation and free electron lasers. Relative comparisons are given within charts of peak brightness.

Published
2001

37. Intense ion beams accelerated by Petawatt-class Lasers

Author

K. Yasuike, Markus Roth, Scott Wilks, Yoshiyuki Takahashi, S. P. Hatchett, Curtis G. Brown, Thomas E. Cowan, Deanna Marie Pennington, M. S. Singh, T. C. Sangster, M. A. Stoyer, Michael D. Perry, R. A. Snavely, J. Johnson, Mark Christl, T. W. Phillips, W. F. Fountain, and M. H. Key

Subjects
Physics, Nuclear and High Energy Physics, Luminosity (scattering theory), Ion beam, Proton, business.industry, Pulse duration, Electron, Laser, Ion, law.invention, Nuclear physics, Optics, Physics::Plasma Physics, law, Physics::Accelerator Physics, business, Instrumentation, Beam (structure)
Abstract

The LLNL Petawatt Laser has achieved focussed intensities up to 6×10 20 W/cm 2 , which has opened a new, higher energy regime of relativistic laser–plasma interactions in which the quiver energy of target electrons exceeds several MeV. Recent experiments revealed an intense, collimated beam of high-energy protons emitted normal to the rear surface of thin, solid targets. Up to 10 13 particles were emitted in a pulse less than 10 ps resulting in a current in the MA regime. With an overall energy content of 30 J, up to 7% of the incident laser energy is converted into protons. The beam shows a broad particle energy spectrum with a sharp cut off above 55 MeV. Based on our current understanding of the accelerating process, it may be possible to shape and focus the ion beam by using special target geometries. With their short pulse duration, high particle energy and large luminosity these beams are promising candidates in numerous applications, such as short-pulse injectors for large accelerators or as the ignitor for fast ignition ICF. Using intense proton beams the fast ignitor concept may become more attractive in heavy-ion fusion due to the possibility to work with indirectly driven targets. Finally, the acceleration is not restricted to protons and using tailored target surfaces may allow acceleration of more massive ions to similar energy per nucleon.

Published
2001

38. Energetic proton generation in ultra-intense laser–solid interactions

Author

Markus Roth, Scott Wilks, R. Snavely, Deanna Marie Pennington, M. S. Singh, Thomas E. Cowan, Stephen P. Hatchett, M. H. Key, A. J. Mackinnon, and A. B. Langdon

Subjects
Physics, Proton, Solar energetic particles, law, Ionization, Bremsstrahlung, Plasma diagnostics, Electron, Atomic physics, Condensed Matter Physics, Laser, law.invention, Ion
Abstract

An explanation for the energetic ions observed in the PetaWatt experiments is presented. In solid target experiments with focused intensities exceeding 1020 W/cm2, high-energy electron generation, hard bremsstrahlung, and energetic protons have been observed on the backside of the target. In this report, an attempt is made to explain the physical process present that will explain the presence of these energetic protons, as well as explain the number, energy, and angular spread of the protons observed in experiment. In particular, we hypothesize that hot electrons produced on the front of the target are sent through to the back off the target, where they ionize the hydrogen layer there. These ions are then accelerated by the hot electron cloud, to tens of MeV energies in distances of order tens of μm, whereupon they end up being detected in the radiographic and spectrographic detectors.

Published
2001

39. Fast Ignition by Intense Laser-Accelerated Proton Beams

Author

Michael D. Perry, R. A. Snavely, Sergei V. Bulanov, E. M. Campbell, J. Johnson, K. Yasuike, Thomas E. Cowan, Markus Roth, W. F. Fountain, Deanna Marie Pennington, Francesco Pegoraro, S. P. Hatchett, Scott Wilks, Howard T. Powell, M. H. Key, Curtis G. Brown, and H. Ruhl

Subjects
Physics, business.industry, General Physics and Astronomy, Implosion, Nova (laser), Fusion power, Laser, law.invention, Nuclear physics, Ignition system, Optics, Physics::Plasma Physics, Hohlraum, law, Physics::Accelerator Physics, business, Inertial confinement fusion, Beam (structure)
Abstract

The concept of fast ignition with inertial confinement fusion (ICF) is a way to reduce the energy required for ignition and burn and to maximize the gain produced by a single implosion. Based on recent experimental findings at the PETAWATT laser at Lawrence Livermore National Laboratory, an intense proton beam to achieve fast ignition is proposed. It is produced by direct laser acceleration and focused onto the pellet from the rear side of an irradiated target and can be integrated into a hohlraum for indirect drive ICF.

Published
2001

40. Nuclear diagnostics for petawatt experiments (invited)

Author

Thomas E. Cowan, Scott Wilks, S. P. Hatchett, Michael D. Perry, R. A. Snavely, E. A. Henry, T. W. Phillips, Michael J. Moran, T. C. Sangster, M. A. Stoyer, M. H. Key, Max Tabak, Deanna Marie Pennington, M. S. Singh, and M. D. Cable

Subjects
Physics, Photofission, Gamma ray, Bremsstrahlung, Nova (laser), Laser science, Laser, law.invention, Nuclear physics, law, Neutron, Atomic physics, Nuclear Experiment, Instrumentation, Inertial confinement fusion
Abstract

With the operation of successively more intense and powerful lasers, such as the NOVA petawatt laser with I∼3×1020 W/cm2, several novel (to laser physics) nuclear diagnostics were used to determine the nature of the laser/matter interaction at the target surface. A broad beam of hot electrons, whose centroid varied from shot to shot, width was remarkably constant, and intensity was about 40% of the incident laser energy was observed. New nuclear phenomenon included photonuclear reactions [e.g., (γ,xn)], photofission of 238U and intense beams of ions. Photonuclear reactions were observed and quantified in Cu, Ni, and Au samples, and produced activation products as neutron deficient as 191Au [a (γ,6n) reaction!], requiring gamma rays exceeding 50 MeV in energy. The spectral features of the gamma-ray source have been investigated by comparing activation ratios in Ni and Au samples, and angular distributions of higher energy photons have been measured with activation of spatially distributed Au samples. Extra...

Published
2001

41. Hot electron diagnostic in a solid laser target byK-shell lines measurement from ultraintense laser–plasma interactions (3×1020 W/cm2,⩽400 J)

Author

S. P. Hatchett, Ken Wharton, K. Yasuike, R. A. Snavely, and M. H. Key

Subjects
Physics, law, Energy conversion efficiency, Electron shell, Pulse duration, Plasma diagnostics, Plasma, Laser power scaling, Atomic physics, Laser, Instrumentation, Intensity (physics), law.invention
Abstract

Characterization of hot electron production from an ultraintense laser–solid target plasma interaction by using a buried molybdenum K-shell fluor layer technique has been reported. Laser energy was typically 400 J and its intensity was from 2×1018 up to 3×1020 W cm−2 at 20 TW to 1 PW laser power by changing pulse duration from 20 ps down to 0.5 ps. X-ray background noise level was significantly greater, i.e., gamma flash, in the shorter pulse experiments. Data analysis procedures for the experiments were developed. The conversion efficiency from the laser energy into the energy, carried by hot electrons, has been estimated to be ∼50% at 3×1020 W cm−2 laser intensity, higher than ∼18% at 1019 W cm−2 and ∼12% at 2×1018 W cm−2 intensity.

Published
2001

42. Petawatt laser system and experiments

Author

A. J. Mackinnon, Michael D. Perry, R. A. Snavely, Brent C. Stuart, E. A. Henry, Michael W. Kartz, Thomas E. Cowan, M. H. Key, S. P. Hatchett, Scott Wilks, T. W. Phillips, Deanna Marie Pennington, M. S. Singh, T. C. Sangster, Jeffrey A. Koch, Curtis G. Brown, S. Herman, Markus Roth, and M. A. Stoyer

Subjects
Physics, Photon, Luminosity (scattering theory), business.industry, Bremsstrahlung, Physics::Optics, Electron, Laser, Atomic and Molecular Physics, and Optics, law.invention, Optics, law, Electrical and Electronic Engineering, business, Adaptive optics, Inertial confinement fusion, Beam (structure)
Abstract

We have developed a hybrid Ti:sapphire-Nd:glass laser system that produces more than 1.5 PW of peak power. The system has produced up to 680 J of energy on target at 1054 nm in a compressed 440/spl plusmn/20-fs pulse by use of 94-cm diffraction gratings. A focused irradiance of up to 6/spl times/10/sup 20/ W/cm/sup 2/ was achieved using an on-axis parabolic mirror and adaptive optic wavefront control. Experiments with the petawatt laser system focused the beam on solid targets and produced a strongly relativistic interaction. Energy content, spectra, and angular pattern of the photon, electron, and ion radiations were diagnosed in a number of ways, including several nuclear activation techniques. Approximately 40-50% of the laser energy was converted to broadly beamed hot electrons, with an associated bremsstrahlung beam. High luminosity ion beams were observed normal to the rear surface of various targets with energies up to /spl ges/55 MeV, representing /spl sim/7% of the laser energy. These and other results are presented.

Published
2000

43. Blast wave diagnostic for the Petawatt laser system

Author

Michael D. Perry, Jave Kane, P. M. Bell, S. P. Hatchett, M. H. Key, Kent Estabrook, Bruce Remington, Charles M. Brown, K. S. Budil, Deanna Marie Pennington, D. M. Gold, and J. A. Koch

Subjects
Physics, Shock wave, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Laser, law.invention, Intensity (physics), Pulse (physics), LASNEX, Optics, law, Plasma diagnostics, business, Instrumentation, Blast wave, Pyrometer
Abstract

We report on a diagnostic to measure the trajectory of a blast wave propagating through a plastic target 400 μm thick. This blast wave is generated by the irradiation of the front surface of the target with ∼400 J of 1 μm laser radiation in a 20 ps pulse focused to a ∼50 μm diameter spot, which produces an intensity in excess of 1018 W/cm2. These conditions approximate a point explosion and a blast wave is predicted to be generated with an initial pressure nearing 1 Gbar which decays as it travels approximately radially outward from the interaction region. We have utilized streaked optical pyrometry of the blast front to determine its time of arrival at the rear surface of the target. Applications of a self-similar Taylor–Sedov blast wave solution allows the amount of energy deposited to be estimated. The experiment, LASNEX design simulations and initial results are discussed.

Published
1999

44. Fast Electron Deposition in Laser Shock Compressed Plastic Targets

Author

D. Neely, S. Ellwi, M. H. Key, M. Koenig, Tom A. Hall, S. J. Rose, P. Fews, V. Masella, Francesca Pisani, A. Bernardinello, J. Krishnan, A. Djaoui, A. Benuzzi, Peter Norreys, and Dimitri Batani

Subjects
Materials science, Optics, law, business.industry, General Physics and Astronomy, Deposition (phase transition), Electron, Laser, business, Shock (mechanics), law.invention
Abstract

We present the first results of fast electron deposition in a laser shock compressed plasma. The interaction of a 3 ps, 15 J laser pulse with solid polyethylene targets is used to produce fast electrons on one side of foil targets and a 2 ns duration laser pulse is used to drive a shock wave into the target from the opposite side. Kα emission from chlorine fluor buried layers is used to measure the electron transport. The hot electron range in the shock compressed plastic is found to be approximately twice as large as the range in the solid density plastic.

Published
1998

46. Experimental Measurements of Hot Electrons Generated by Ultraintense (>1019W/cm2) Laser-Plasma Interactions on Solid-Density Targets

Author

M. H. Key, Michael D. Perry, John Moody, Ken Wharton, Bruce Hammel, C. Joshi, Scott Wilks, Victor Yanovsky, S. P. Hatchett, and A. A. Offenberger

Subjects
Electromagnetic field, Physics, Energy conversion efficiency, General Physics and Astronomy, Plasma, Electron, Laser, law.invention, Pulse (physics), symbols.namesake, law, symbols, Energy transformation, Atomic physics, Lorentz force
Abstract

We present the first in-target measurements of the electrons produced by an ultraintense $(Ig{10}^{19}\mathrm{W}/{\mathrm{cm}}^{2})$ laser pulse incident on a massive solid target. Total conversion efficiency, mean electron energy, and electron cone-angle measurements are presented. A relationship between the target material and the mean electron energy is also discussed.

Published
1998

47. Hot electron production and heating by hot electrons in fast ignitor research

Author

M. D. Cable, Barbara F. Lasinski, Kent Estabrook, J. D. Kilkenny, A. J. Mackinnon, Michael D. Perry, Thomas E. Cowan, Ken Wharton, M. A. Stoyer, T. C. Sangster, Richard W. Lee, William L. Kruer, S. P. Hatchett, M. Tsukamoto, D. E. Hinkel, E. A. Henry, T. J. Phillips, M. H. Key, Max Tabak, G. L. Tietbohl, Scott Wilks, J. D. Moody, Deanna Marie Pennington, M. S. Singh, A. B. Langdon, A. A. Offenberger, B. J. MacGowan, Michael J. Moran, B. A. Hammel, and J. A. Koch

Subjects
Physics, Bremsstrahlung, Plasma, Condensed Matter Physics, IGNITOR, Laser, law.invention, Ignition system, Physics::Plasma Physics, law, Plasma diagnostics, Astrophysics::Earth and Planetary Astrophysics, Atomic physics, Inertial confinement fusion, Hot electron
Abstract

In an experimental study of the physics of fast ignition the characteristics of the hot electron source at laser intensities up to 10(to the 20th power) Wcm{sup -2} and the heating produced at depth by hot electrons have been measured. Efficient generation of hot electrons but less than the anticipated heating have been observed.

Published
1998

48. Comparison of Drive-Seeded Modulations in Planar Foils for 0.35 and 0.53μmLaser Drive

Author

M. H. Key, B. A. Hammel, R. J. Wallace, Daniel H. Kalantar, S. V. Weber, J. D. Kilkenny, S. G. Glendinning, J. P. Knauer, Deanna Marie Pennington, Bruce Remington, Joshua E. Rothenberg, and S. N. Dixit

Subjects
Physics, LASNEX, Planar, law, Laser intensity, Modulation (music), General Physics and Astronomy, Atomic physics, Laser, Inertial confinement fusion, law.invention
Abstract

Laser-speckle-seeded modulations in laser-driven targets have been observed with the Nova laser using 0.53 and $0.35\ensuremath{\mu}\mathrm{m}$ drive. The $0.35\ensuremath{\mu}\mathrm{m}$ drive produced larger modulations (equivalent to $3.3\ensuremath{\mu}\mathrm{m}$ rms surface finish) than $0.53\ensuremath{\mu}\mathrm{m}$ drive ( $2.0\ensuremath{\mu}\mathrm{m}$ rms). The laser intensity was $\ensuremath{\sim}{10}^{13}\mathrm{W}/{\mathrm{cm}}^{2}$, similar to that suggested for directly driven ignition targets during the first several ns. LASNEX simulations of this thermal smoothing effect in both the rms and spectrum agree with the $0.53\ensuremath{\mu}\mathrm{m}$ drive data, and are about 15% lower than the measured results with $0.35\ensuremath{\mu}\mathrm{m}$ drive.

Published
1998

49. Time-resolved X-ray spectroscopy of deeply buried tracer layers as a density and temperature diagnostic for the fast ignitor

Author

A. A. Offenberger, Max Tabak, S. P. Hatchett, Ken Wharton, Kent Estabrook, R. J. Wallace, Richard W. Lee, Scott Wilks, J. D. Moody, Deanna Marie Pennington, Christina Back, Victor Yanovsky, Curtis G. Brown, J. A. Koch, M. H. Key, Otto Landen, B. A. Hammel, J. D. Kilkenny, and Michael D. Perry

Subjects
X-ray spectroscopy, Materials science, Plasma, Electron, Condensed Matter Physics, IGNITOR, Laser, Atomic and Molecular Physics, and Optics, Spectral line, law.invention, law, Emission spectrum, Electrical and Electronic Engineering, Atomic physics, Inertial confinement fusion
Abstract

The fast ignitor concept for inertial confinement fusion relies on the generation of hot electrons, produced by a short-pulse ultrahigh intensity laser, which propagate through high-density plasma to deposit their energy in the compressed fuel core and heat it to ignition. In preliminary experiments designed to investigate deep heating of high-density matter, we used a 20 joule, 0.5–30 ps laser to heat solid targets, and used emission spectroscopy to measure plasma temperatures and densities achieved at large depths (2–20 microns) away from the initial target surface. The targets consisted of an Al tracer layer buried within a massive CH slab; H-like and He-like line emission was then used to diagnose plasma conditions. We observe spectra from tracer layers buried up to 20 microns deep, measure emission durations of up to 200 ps, measure plasma temperatures up to Te=650 eV, and measure electron densities above 1023 cm−3. Analysis is in progress, but the data are in reasonable agreement with heating simulations when space-charge induced inhibition is included in hot-electron transport, and this supports the conclusion that the deep heating is initiated by hot electrons.

Published
1998

50. [Untitled]

Author

E. M. Campbell, A. J. Mackinnon, Michael D. Perry, R. A. Snavely, M. H. Key, S. P. Hatchett, Deanna Marie Pennington, M. S. Singh, Thomas E. Cowan, A. A. Offenberger, T. C. Sangster, A. B. Langdon, Ken Wharton, Barbara F. Lasinski, J. A. Koch, M. Tsukamoto, M. A. Stoyer, T. J. Phillips, Scott Wilks, and E. A. Henry

Subjects
Physics, Nuclear and High Energy Physics, Thermonuclear fusion, Nova (laser), Fusion power, Laser, law.invention, Nuclear physics, Ignition system, Nuclear Energy and Engineering, Physics::Plasma Physics, law, Nuclear fusion, National Ignition Facility, Inertial confinement fusion
Abstract

A model of energy gain induced by fast ignition of thermonuclear burn in compressed deuterium-tritium fuel, is used to show the potential for 300× gain with a driver energy of 1 MJ, if the National Ignition Facility (NIF) were to be adapted for fast ignition. The physics of fast ignition has been studied using a petawatt laser facility at the Lawrence Livermore National Laboratory. Laser plasma interaction in a preformed plasma on a solid target leads to relativistic self-focusing evidenced by x-ray images. Absorption of the laser radiation transfers energy to an intense source of relativistic electrons. Good conversion efficiency into a wide angular distribution is reported. Heating by the electrons in solid density CD2 produces 0.5 to 1 keV temperature, inferred from the D-D thermo-nuclear neutron yield.

Published
1998

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