Your search keyword '"D R Rusby"' showing total 10 results

1. Energy absorption and coupling to electrons in the transition from surface- to volume-dominant intense laser–plasma interaction regimes

Author

S D R Williamson, R J Gray, M King, R Wilson, R J Dance, C Armstrong, D R Rusby, C Brabetz, F Wagner, B Zielbauer, V Bagnoud, D Neely, and P McKenna

Subjects

intense laser–solid interactions, laser absorption in dense plasma, relativistic self induced transparency, Science, Physics, QC1-999

Abstract

The coupling of laser energy to electrons is fundamental to almost all topics in intense laser–plasma interactions, including laser-driven particle and radiation generation, relativistic optics, inertial confinement fusion and laboratory astrophysics. We report measurements of total energy absorption in foil targets ranging in thickness from 20 μ m, for which the target remains opaque and surface interactions dominate, to 40 nm, for which expansion enables relativistic-induced transparency and volumetric interactions. We measure a total peak absorption of ∼80% at an optimum thickness of ∼380 nm. For thinner targets, for which some degree of transparency occurs, although the total absorption decreases, the number of energetic electrons escaping the target increases. 2D particle-in-cell simulations indicate that this results from direct laser acceleration of electrons as the intense laser pulse propagates within the target volume. The results point to a trade-off between total energy coupling to electrons and efficient acceleration to higher energies.

Published

2020

2. Diagnosis of Weibel instability evolution in the rear surface density scale lengths of laser solid interactions via proton acceleration

Author

G G Scott, C M Brenner, V Bagnoud, R J Clarke, B Gonzalez-Izquierdo, J S Green, R I Heathcote, H W Powell, D R Rusby, B Zielbauer, P McKenna, and D Neely

Subjects

laser ion acceleration, Weibel instability, electron transport, fast ignition, laser plasma insability, Science, Physics, QC1-999

Abstract

It is shown for the first time that the spatial and temporal distribution of laser accelerated protons can be used as a diagnostic of Weibel instability presence and evolution in the rear surface scale lengths of a solid density target. Numerical modelling shows that when a fast electron beam is injected into a decreasing density gradient on the target rear side, a magnetic instability is seeded with an evolution which is strongly dependent on the density scale length. This is manifested in the acceleration of a filamented proton beam, where the degree of filamentation is also found to be dependent on the target rear scale length. Furthermore, the energy dependent spatial distribution of the accelerated proton beam is shown to provide information on the instability evolution on the picosecond timescale over which the protons are accelerated. Experimentally, this is investigated by using a controlled prepulse to introduce a target rear scale length, which is varied by altering the time delay with respect to the main pulse, and similar trends are measured. This work is particularly pertinent to applications using laser pulse durations of tens of picoseconds, or where a micron level density scale length is present on the rear of a solid target, such as proton-driven fast ignition, as the resultant instability may affect the uniformity of fuel energy coupling.

Published

2017

3. Proton acceleration enhanced by a plasma jet in expanding foils undergoing relativistic transparency

Author

H W Powell, M King, R J Gray, D A MacLellan, B Gonzalez-Izquierdo, L C Stockhausen, G Hicks, N P Dover, D R Rusby, D C Carroll, H Padda, R Torres, S Kar, R J Clarke, I O Musgrave, Z Najmudin, M Borghesi, D Neely, and P McKenna

Subjects

laser–plasma interactions, relativistic transparency, ion acceleration, plasma jet, Science, Physics, QC1-999

Abstract

Ion acceleration driven by the interaction of an ultraintense (2 × 10 ^20 W cm ^−2 ) laser pulse with an ultrathin ( $\leqslant 40$ nm) foil target is experimentally and numerically investigated. Protons accelerated by sheath fields and via laser radiation pressure are angularly separated and identified based on their directionality and signature features (e.g. transverse instabilities) in the measured spatial-intensity distribution. A low divergence, high energy proton component is also detected when the heated target electrons expand and the target becomes relativistically transparent during the interaction. 2D and 3D particle-in-cell simulations indicate that under these conditions a plasma jet is formed at the target rear, supported by a self-generated azimuthal magnetic field, which extends into the expanded layer of sheath-accelerated protons. Electrons trapped within this jet are directly accelerated to super-thermal energies by the portion of the laser pulse transmitted through the target. The resulting streaming of the electrons into the ion layers enhances the energy of protons in the vicinity of the jet. Through the addition of a controlled prepulse, the maximum energy of these protons is demonstrated experimentally and numerically to be sensitive to the picosecond rising edge profile of the laser pulse.

Published

2015

4. Azimuthal asymmetry in collective electron dynamics in relativistically transparent laser–foil interactions

Author

R J Gray, D A MacLellan, B Gonzalez-Izquierdo, H W Powell, D C Carroll, C D Murphy, L C Stockhausen, D R Rusby, G G Scott, R Wilson, N Booth, D R Symes, S J Hawkes, R Torres, M Borghesi, D Neely, and P McKenna

Subjects

laser-plasma interaction, ion acceleration, charged particle dynamics, Science, Physics, QC1-999

Abstract

Asymmetry in the collective dynamics of ponderomotively-driven electrons in the interaction of an ultraintense laser pulse with a relativistically transparent target is demonstrated experimentally. The 2D profile of the beam of accelerated electrons is shown to change from an ellipse aligned along the laser polarization direction in the case of limited transparency, to a double-lobe structure aligned perpendicular to it when a significant fraction of the laser pulse co-propagates with the electrons. The temporally-resolved dynamics of the interaction are investigated via particle-in-cell simulations. The results provide new insight into the collective response of charged particles to intense laser fields over an extended interaction volume, which is important for a wide range of applications, and in particular for the development of promising new ultraintense laser-driven ion acceleration mechanisms involving ultrathin target foils.

Published

2014

5. Enhanced electron acceleration by high-intensity lasers in extended (confined) preplasma in cone targets

Author

D. R. Rusby, G. E. Cochran, A. Aghedo, F. Albert, C. D. Armstrong, A. Haid, A. J. Kemp, S. M. Kerr, P. M. King, N. Lemos, M. J.-E. Manuel, T. Ma, A. G. MacPhee, I. Pagano, A. Pak, G. G. Scott, C. W. Siders, R. A. Simpson, M. Sinclair, S. C. Wilks, G. J. Williams, and A. J. Mackinnon

Subjects

Condensed Matter Physics

Abstract

We report on experimental results from a high-intensity laser interaction with cone targets that increase the number (×3) and temperature (×3) of the measured hot electrons over a traditional planar target. This increase is caused by a substantial increase in the plasma density within the cone target geometry, which was induced by 17 ± 9 mJ prepulse that arrived 1.5 ns prior to the main high intensity (>1019 W/cm2). Three-dimensional hydrodynamic simulations are conducted using hydra which show that the cone targets create substantially longer and denser plasma than planar targets due to the geometric confinement of the expanding plasma. The density within the cone is a several hundred-micron plasma “shelf” with a density of approximately 1020 n e/cc. The hydra simulated plasma densities are used as the initial conditions for two-dimensional particle-in-cell simulations using EPOCH. These simulations show that the main acceleration mechanism is direct-laser-acceleration, with close agreement between experimentally measured and simulated electron temperatures. Further analysis is conducted to investigate the acceleration of the electrons within the long plasma generated within a compound parabolic concentrator by the prepulse.

Published

2023

6. Role of magnetic field evolution on filamentary structure formation in intense laser–foil interactions

Author

M. King, N. M. H. Butler, R. Wilson, R. Capdessus, R. J. Gray, H. W. Powell, R. J. Dance, H. Padda, B. Gonzalez-Izquierdo, D. R. Rusby, N. P. Dover, G. S. Hicks, O. C. Ettlinger, C. Scullion, D. C. Carroll, Z. Najmudin, M. Borghesi, D. Neely, P. McKenna

Published

2019

7. EMP control and characterization on high-power laser systems

Author

P. Bradford, N. C. Woolsey, G. G. Scott, G. Liao, H. Liu, Y. Zhang, B. Zhu, C. Armstrong, S. Astbury, C. Brenner, P. Brummitt, F. Consoli, I. East, R. Gray, D. Haddock, P. Huggard, P. J. R. Jones, E. Montgomery, I. Musgrave, P. Oliveira, D. R. Rusby, C. Spindloe, B. Summers, E. Zemaityte, Z. Zhang, Y. Li, P. McKenna, D. Neely

Published

2018

8. Bremsstrahlung emission profile from intense laser-solid interactions as a function of laser focal spot size.

Author

C D Armstrong, C M Brenner, E Zemaityte, G G Scott, D R Rusby, G Liao, H Liu, Y Li, Z Zhang, Y Zhang, B Zhu, P Bradford, N C Woolsey, P Oliveira, C Spindloe, W Wang, P McKenna, and D Neely

Subjects

BREMSSTRAHLUNG, X-ray emission spectroscopy, ELECTRON transport, RADIOGRAPHY, ELECTRONS

Abstract

The bremsstrahlung x-ray emission profile from high intensity laser-solid interactions provides valuable insight to the internal fast electron transport. Using penumbral imaging, we characterise the spatial profile of this bremsstrahlung source as a function of laser intensity by incrementally increasing the laser focal spot size on target. The experimental data shows a dual-source structure; one from the central channel of electrons, the second a larger substrate source from the recirculating electron current. The results demonstrate than an order of magnitude improvement in the intensity contrast between the two x-ray sources is achieved with a large focal spot, indicating preferable conditions for applications in radiography. An analytical model is derived to describe the transport of suprathermal electron populations that contribute to substrate and central channel sources through a target. The model is in good agreement with the experimental results presented here and furthermore is applied to predict laser intensities for achieving optimum spatial contrast for a variety of target materials and thicknesses. [ABSTRACT FROM AUTHOR]

Published

2019

9. Laser-driven x-ray and neutron source development for industrial applications of plasma accelerators.

Author

C M Brenner, S R Mirfayzi, D R Rusby, C Armstrong, A Alejo, L A Wilson, R Clarke, H Ahmed, N M H Butler, D Haddock, A Higginson, A McClymont, C Murphy, M Notley, P Oliver, R Allott, C Hernandez-Gomez, S Kar, P McKenna, and D Neely

Subjects

PLASMA accelerators, LASER beams, X-rays, NEUTRON sources, BREMSSTRAHLUNG

Abstract

Pulsed beams of energetic x-rays and neutrons from intense laser interactions with solid foils are promising for applications where bright, small emission area sources, capable of multi-modal delivery are ideal. Possible end users of laser-driven multi-modal sources are those requiring advanced non-destructive inspection techniques in industry sectors of high value commerce such as aerospace, nuclear and advanced manufacturing. We report on experimental work that demonstrates multi-modal operation of high power laser-solid interactions for neutron and x-ray beam generation. Measurements and Monte Carlo radiation transport simulations show that neutron yield is increased by a factor ~2 when a 1 mm copper foil is placed behind a 2 mm lithium foil, compared to using a 2 cm block of lithium only. We explore x-ray generation with a 10 picosecond drive pulse in order to tailor the spectral content for radiography with medium density alloy metals. The impact of using  >1 ps pulse duration on laser-accelerated electron beam generation and transport is discussed alongside the optimisation of subsequent bremsstrahlung emission in thin, high atomic number target foils. X-ray spectra are deconvolved from spectrometer measurements and simulation data generated using the GEANT4 Monte Carlo code. We also demonstrate the unique capability of laser-driven x-rays in being able to deliver single pulse high spatial resolution projection imaging of thick metallic objects. Active detector radiographic imaging of industrially relevant sample objects with a 10 ps drive pulse is presented for the first time, demonstrating that features of 200 μm size are resolved when projected at high magnification. [ABSTRACT FROM AUTHOR]

Published

2016

10. Role of lattice structure and low temperature resistivity in fast-electron-beam filamentation in carbon.

Author

R J Dance, N M H Butler, R J Gray, D A MacLellan, D R Rusby, G G Scott, B Zielbauer, V Bagnoud, H Xu, A P L Robinson, M P Desjarlais, D Neely, and P McKenna

Subjects

CRYSTAL lattices, CRYSTAL structure, LOW temperatures, ELECTRON beams, FILAMENTATION instability, CARBON, ELECTRICAL resistivity

Abstract

The influence of low temperature (eV to tens-of-eV) electrical resistivity on the onset of the filamentation instability in fast-electron transport is investigated in targets comprising of layers of ordered (diamond) and disordered (vitreous) carbon. It is shown experimentally and numerically that the thickness of the disordered carbon layer influences the degree of filamentation of the fast-electron beam. Strong filamentation is produced if the thickness is of the order of 60 μm or greater, for an electron distribution driven by a sub-picosecond, mid-1020 Wcm−2 laser pulse. It is shown that the position of the vitreous carbon layer relative to the fast-electron source (where the beam current density and background temperature are highest) does not have a strong effect because the resistive filamentation growth rate is high in disordered carbon over a wide range of temperatures up to the Spitzer regime. [ABSTRACT FROM AUTHOR]

Published

2016