Your search keyword '"O. C. Ettlinger"' showing total 11 results

1. Selective Ion Acceleration by Intense Radiation Pressure

Author

P. Martin, Aodhan McIlvenny, Nicola Booth, Satya Kar, Paul McKenna, Marco Borghesi, Domenico Doria, Zulfikar Najmudin, Lorenzo Romagnani, Andrea Macchi, G. Hicks, O. C. Ettlinger, David Neely, Emma Ditter, Graeme Scott, Hamad Ahmed, S. D. R. Williamson, Laboratoire pour l'utilisation des lasers intenses (LULI), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-École polytechnique (X)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Centre for Plasma Physics, Queen's University [Belfast] (QUB), STFC Rutherford Appleton Laboratory (RAL), Science and Technology Facilities Council (STFC), Blackett Laboratory, Imperial College London, and University of Strathclyde [Glasgow]

Subjects

QC717, Materials science, plasma mirror, laser, contrast, Proton, [PHYS.PHYS.PHYS-ACC-PH]Physics [physics]/Physics [physics]/Accelerator Physics [physics.acc-ph], General Physics and Astronomy, Plasma, Laser, 01 natural sciences, Fluence, 7. Clean energy, 010305 fluids & plasmas, Ion, law.invention, Acceleration, Radiation pressure, law, Physics::Plasma Physics, 0103 physical sciences, Physics::Accelerator Physics, Particle-in-cell, Atomic physics, 010306 general physics, Nuclear Experiment

Abstract

Accessing novel ion acceleration mechanisms, such as Radiation Pressure Acceleration (RPA), is a promising route to generate high energy beams of both light and heavy ions [1]. In particular, the Light Sail (LS) regime predicts high efficiency, mono-energetic beams and can be accessed with currently available high power laser facilities with the use of ultra-thin foils and circular polarisation [2-4]. In recent experiments at the GEMINI laser facility (RAL, UK), target bulk (carbon) ions were favourably accelerated in the LS-RPA regime up to 33MeV/nucleon at an optimal carbon foil thickness of 15nm, whereas protons only reached energies of 18 MeV. This result, which differs from what is typically observed in laser-solid interactions, where protons are always accelerated more efficiently than heavier ions, is interpreted with the support of multi-dimensional Particle in Cell (PIC) simulations. While the 40fs pulse was temporally cleaned by a double plasma mirror arrangement to increase the laser contrast to 10-14 at the ns timescale, it is shown that the limited preceding laser fluence incident on the target on the ps scale causes target expansion, with protons, being lighter, escaping from the interaction region. This leaves a pre-dominantly carbon plasma which, for circular polarization, is accelerated by RPA, with proton energies determined instead by plasma expansion and sheath effects. It is shown through simulations that controlling the laser temporal profile and plasma mirror activation opens up a promising route for controlling which ion species is preferentially accelerated in the RPA regime. This has particular importance as

Published

2021

2. LhARA: The Laser-hybrid Accelerator for Radiobiological Applications

Author

Karen J. Kirkby, Zulfikar Najmudin, Monika Puchalska, William Shields, Ruth Mclauchlan, Titus-Stefan Dascalu, Galen Aymar, Tobias Becker, Stephen Gibson, Jason L. Parsons, Kenneth Long, Giuseppe Schettino, Paul McKenna, Wendy Jones, Marco Borghesi, Kevin M. Prise, Dorothy M. Gujral, T. Greenshaw, Colin G. Whyte, Ceri Brenner, Rachel Xiao, Philip Burrows, Sylvia Gruber, Stephen Towe, Jaroslaw Pasternak, J. Thomason, Peter Weightman, Stewart Boogert, J. Matheson, S.L. Smith, Robert Bingham, O. C. Ettlinger, Juergen Pozimski, H. T. Lau, Wayne Luk, Jean-Baptiste Lagrange, A. Kurup, Claire Hardiman, P. N. Ratoff, Jonathan R Hughes, Science and Technology Facilities Council (STFC), Engineering & Physical Science Research Council (E, Science and Technology Facilities Council [2006-2012], and The John Adams Institute for Accelerator Science Capital Equipment 2018

Subjects

laser-driven acceleration, Proton, fixed-field alternating-gradient acceleration, Quantitative Biology::Tissues and Organs, Materials Science (miscellaneous), Physics::Medical Physics, Biophysics, General Physics and Astronomy, Physics and Astronomy(all), novel acceleration, 01 natural sciences, law.invention, Ion, Ionizing radiation, Nuclear physics, law, 0103 physical sciences, Physical and Theoretical Chemistry, 010306 general physics, QC, Mathematical Physics, Physics, proton beam therapy (PBT), Plasma, plasma lens, Laser, lcsh:QC1-999, Lens (optics), radiobiology, Physics::Accelerator Physics, ion beam therapy, Nucleon, lcsh:Physics, Beam (structure)

Abstract

The “Laser-hybrid Accelerator for Radiobiological Applications,” LhARA, is conceived as a novel, flexible facility dedicated to the study of radiobiology. The technologies demonstrated in LhARA, which have wide application, will be developed to allow particle-beam therapy to be delivered in a new regimen, combining a variety of ion species in a single treatment fraction and exploiting ultra-high dose rates. LhARA will be a hybrid accelerator system in which laser interactions drive the creation of a large flux of protons or light ions that are captured using a plasma (Gabor) lens and formed into a beam. The laser-driven source allows protons and ions to be captured at energies significantly above those that pertain in conventional facilities, thus evading the current space-charge limit on the instantaneous dose rate that can be delivered. The laser-hybrid approach, therefore, will allow the radiobiology that determines the response of tissue to ionizing radiation to be studied with protons and light ions using a wide variety of time structures, spectral distributions, and spatial configurations at instantaneous dose rates up to and significantly beyond the ultra-high dose-rate “FLASH” regime. It is proposed that LhARA be developed in two stages. In the first stage, a programme of in vitro radiobiology will be served with proton beams with energies between 10 and 15 MeV. In stage two, the beam will be accelerated using a fixed-field alternating-gradient accelerator (FFA). This will allow experiments to be carried out in vitro and in vivo with proton beam energies of up to 127 MeV. In addition, ion beams with energies up to 33.4 MeV per nucleon will be available for in vitro and in vivo experiments. This paper presents the conceptual design for LhARA and the R&D programme by which the LhARA consortium seeks to establish the facility.

Published

2020

3. Dynamics of laser-driven heavy-ion acceleration clarified by ion charge states

Author

Masaki Kando, Karl Zeil, E. J. Ditter, Tim Ziegler, Ulrich Schramm, James K. Koga, Akito Sagisaka, Hiromitsu Kiriyama, T. A. Pikuz, M. A. Alkhimova, G. Hicks, Yasuhiko Sentoku, N. Iwata, Zulfikar Najmudin, H. Sakaki, Kiminori Kondo, Alexander S. Pirozhkov, Masayasu Hata, Hazel Lowe, Ko. Kondo, Mamiko Nishiuchi, T. Miyahara, Nicholas P. Dover, Yukinobu Watanabe, O. C. Ettlinger, and A. Ya. Faenov

Subjects

Acceleration, Materials science, Physics::Plasma Physics, law, Dynamics (mechanics), Heavy ion, Atomic physics, Laser, law.invention, Ion

Abstract

Motivated by the development of next-generation heavy-ion sources, we have investigated the ionization and acceleration dynamics of an ultraintense laser-driven high- Z silver target, experimentally, numerically, and analytically. Using a novel ion measurement technique allowing us to uniquely identify silver ions, we experimentally demonstrate generation of highly charged silver ions ( Z ∗ = 45 + 2 − 2 ) with energies of > 20 MeV/nucleon ( > 2.2 GeV) from submicron silver targets driven by a laser with intensity 5 × 10 21 W / cm 2 , with increasing ion energy and charge state for decreasing target thickness. We show that although target pre-expansion by the unavoidable rising edge of state-of-the-art high-power lasers can limit proton energies, it is advantageous for heavy-ion acceleration. Two-dimensional particle-in-cell simulations show that the Joule heating in the target bulk results in a high temperature ( ∼ 10 keV ) solid density plasma, leading to the generation of high flux highly charged ions ( Z ∗ = 40 + 2 − 2 , ≳ 10 MeV / nucleon ) via electron collisional ionization, which are extracted and accelerated with a small divergence by an extreme sheath field at the target rear. However, with reduced target thickness this favorable acceleration is degraded due to the target deformation via laser hole boring, which accompanies higher energy ions with higher charge states but in an uncontrollable manner. Our elucidation of the fundamental processes of high-intensity laser-driven ionization and ion acceleration provides a path for improving the control and parameters of laser-driven heavy-ion sources, a key component for next-generation heavy-ion accelerators.

Published

2020

4. Demonstration of repetitive energetic proton generation by ultra-intense laser interaction with a tape target

Author

Masayasu Hata, James K. Koga, Nicholas P. Dover, A. Ya. Faenov, G. Hicks, Alexander S. Pirozhkov, Mamiko Nishiuchi, Yasuhiko Sentoku, T. A. Pikuz, Ko. Kondo, Masaki Kando, E. J. Ditter, H. Sakaki, Akito Sagisaka, O. C. Ettlinger, Yukinobu Watanabe, T. Miyahara, Hiromitsu Kiriyama, M. A. Alkhimova, Kotaro Kondo, Zulfikar Najmudin, Tim Ziegler, Ulrich Schramm, N. Iwata, Karl Zeil, and Hazel Lowe

Subjects

Nuclear and High Energy Physics, Radiation, Materials science, Proton, business.industry, Laser, 01 natural sciences, 010305 fluids & plasmas, Ion, Power (physics), law.invention, Acceleration, Optics, law, 0103 physical sciences, Irradiation, 010306 general physics, business, Scaling, Energy (signal processing)

Abstract

High power laser systems are an attractive driver for compact energetic ion sources. We demonstrate repetitive acceleration at 0.1 Hz of proton beams up to 40 MeV from a reeled tape target irradiated by ultra-high intensities up to 5 × 1021 Wcm − 2 and laser energies ≈ 15 J using the J-KAREN-P laser system. We investigate the stability of the source and its behaviour with laser spot focal size. We compare the scaling of proton energy with laser energy to a recently developed analytical model, and also demonstrate that it is possible to reach energies up to 50 MeV on a single shot with a lower laser energy ≈ 10 J by using a thinner target, motivating development of high repetition targetry suitable for thinner targets.

Published

2020

5. High-Intensity Laser-Driven Oxygen Source from CW Laser-Heated Titanium Tape Targets

Author

Kotaro Kondo, Hazel Lowe, Tim Ziegler, Zulfikar Najmudin, Karl Zeil, Nicholas P. Dover, Mamiko Nishiuchi, Kiminori Kondo, Masaki Kando, G. Hicks, O. C. Ettlinger, Hiromitsu Kiriyama, Yukinobu Watanabe, Ulrich Schramm, Hironao Sakaki, Emma Ditter, and T. Miyahara

Subjects

Materials science, Proton, General Chemical Engineering, chemistry.chemical_element, 01 natural sciences, Oxygen, 010305 fluids & plasmas, law.invention, Inorganic Chemistry, Acceleration, law, 0103 physical sciences, lcsh:QD901-999, General Materials Science, high-power laser, laser-driven heavy ion acceleration, 010306 general physics, CW laser heating, 0306 Physical Chemistry (incl. Structural), oxygen ion source, business.industry, Ti:sapphire laser, surface treatment, Condensed Matter Physics, Laser, Ti Sapphire laser, chemistry, Optoelectronics, lcsh:Crystallography, business, Layer (electronics), Intensity (heat transfer), Titanium

Abstract

The interaction of high-intensity laser pulses with solid targets can be used as a highly charged, energetic heavy ion source. Normally, intrinsic contaminants on the target surface suppress the performance of heavy ion acceleration from a high-intensity laser&ndash, target interaction, resulting in preferential proton acceleration. Here, we demonstrate that CW laser heating of 5 &micro, m titanium tape targets can remove contaminant hydrocarbons in order to expose a thin oxide layer on the metal surface, ideal for the generation of energetic oxygen beams. This is demonstrated by irradiating the heated targets with a PW class high-power laser at an intensity of 5 &times, 1021 W/cm2, showing enhanced acceleration of oxygen ions with a non-thermal-like distribution. Our new scheme using a CW laser-heated Ti tape target is promising for use as a moderate repetition energetic oxygen ion source for future applications.

Published

2020

6. Simulation of a radiobiology facility for the Centre for the Clinical Application of Particles

Author

A. Kurup, H. T. Lau, L. Murgatroyd, Laurence Nevay, O. C. Ettlinger, R. Taylor, Zulfikar Najmudin, Jaroslaw Pasternak, Jürgen Pozimski, G.J. Barber, John Yarnold, Kenneth Long, William Shields, V. Blackmore, Sylvia Gruber, Engineering & Physical Science Research Council (E, Science and Technology Facilities Council (STFC), and Imperial College Trust

Subjects

SELECTION, Accelerator Physics (physics.acc-ph), Ion beam, Nuclear engineering, Biophysics, General Physics and Astronomy, Laser, FOS: Physical sciences, RELATIVE BIOLOGICAL EFFECTIVENESS, physics.med-ph, Tracking (particle physics), PROTON, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Radiology, Nuclear Medicine and imaging, Ion, BEAM THERAPY, 11 Medical and Health Sciences, physics.acc-ph, Physics, Science & Technology, 02 Physical Sciences, Detector, Radiology, Nuclear Medicine & Medical Imaging, Radiobiology, Particle accelerator, Beam, General Medicine, DOSIMETRY, 06 Biological Sciences, Models, Theoretical, Physics - Medical Physics, IRRADIATION, Lens (optics), Nuclear Medicine & Medical Imaging, 030220 oncology & carcinogenesis, Particle, Physics::Accelerator Physics, Physics - Accelerator Physics, Medical Physics (physics.med-ph), Particle Accelerators, Life Sciences & Biomedicine, Beam (structure)

Abstract

The Centre for the Clinical Application of Particles' Laser-hybrid Accelerator for Radiobiological Applications (LhARA) facility is being studied and requires simulation of novel accelerator components (such as the Gabor lens capture system), detector simulation and simulation of the ion beam interaction with cells. The first stage of LhARA will provide protons up to 15 MeV for in vitro studies. The second stage of LhARA will use a fixed-field accelerator to increase the energy of the particles to allow in vivo studies with protons and in vitro studies with heavier ions. BDSIM, a Geant4 based accelerator simulation tool, has been used to perform particle tracking simulations to verify the beam optics design done by BeamOptics and these show good agreement. Design parameters were defined based on an EPOCH simulation of the laser source and a series of mono-energetic input beams were generated from this by BDSIM. The tracking results show the large angular spread of the input beam (0.2 rad) can be transported with a transmission of almost 100% whilst keeping divergence at the end station very low (

Published

2019

7. Low-noise time-resolved optical sensing of electromagnetic pulses from petawatt laser-matter interactions

Author

T. Robinson, E. J. Ditter, Nicholas Stuart, Samuel Eardley, M. M. Notley, Roland Smith, Fabrizio Consoli, G. Hicks, Zulfikar Najmudin, Samuel Giltrap, O. C. Ettlinger, R. De Angelis, Consoli, F., De Angelis, R., Engineering & Physical Science Research Council (E, and Science and Technology Facilities Council (STFC)

Subjects

Optical fiber, Materials science, Field (physics), Science, ELECTRIC-FIELD MEASUREMENTS, 01 natural sciences, Signal, Article, 010305 fluids & plasmas, law.invention, 010309 optics, symbols.namesake, Optics, law, Electric field, TARGET CHAMBER, 0103 physical sciences, Faraday effect, FACILITY, MODULATION, Electromagnetic pulse, Multidisciplinary, Science & Technology, PLASMA, business.industry, KH2PO4, Laser, Pockels effect, Multidisciplinary Sciences, CRYSTALS, LIGHT, symbols, Medicine, Science & Technology - Other Topics, business, ELECTROOPTIC SENSORS, GENERATION

Abstract

We report on the development and deployment of an optical diagnostic for single-shot measurement of the electric-field components of electromagnetic pulses from high-intensity laser-matter interactions in a high-noise environment. The electro-optic Pockels effect in KDP crystals was used to measure transient electric fields using a geometry easily modifiable for magnetic field detection via Faraday rotation. Using dielectric sensors and an optical fibre-based readout ensures minimal field perturbations compared to conductive probes and greatly limits unwanted electrical pickup between probe and recording system. The device was tested at the Vulcan Petawatt facility with 1020 W cm−2 peak intensities, the first time such a diagnostic has been used in this regime. The probe crystals were located ~1.25 m from target and did not require direct view of the source plasma. The measured signals compare favourably with previously reported studies from Vulcan, in terms of the maximum measured intra-crystal field of 10.9 kV/m, signal duration and detected frequency content which was found to match the interaction chamber’s horizontal-plane fundamental harmonics of 76 and 101 MHz. Methods for improving the diagnostic for future use are also discussed in detail. Orthogonal optical probes offer a low-noise alternative for direct simultaneous measurement of each vector field component.

Published

2017

8. Staging and laser acceleration of ions in underdense plasma

Author

Igor Pogorelsky, Daniel Gordon, M. Babzien, Antonio Ting, Zulfikar Najmudin, Dmitri Kaganovich, Nicholas P. Dover, Yu-hsin Chen, Mikhail Polyanskiy, O. C. Ettlinger, Chenlong Miao, Bahman Hafizi, and Michael Helle

Subjects

Acceleration, Physics::Plasma Physics, Chemistry, Waves in plasmas, law, Plasma, Atomic physics, Phase velocity, Plasma acceleration, Laser, Plasma density, Ion, law.invention

Abstract

Accelerating ions from rest in a plasma requires extra considerations because of their heavy mass. Low phase velocity fields or quasi-electrostatic fields are often necessary, either by operating above or near the critical density or by applying other slow wave generating mechanisms. Solid targets have been a favorite and have generated many good results. High density gas targets have also been reported to produce energetic ions. It is interesting to consider acceleration of ions in laser-driven plasma configurations that will potentially allow continuous acceleration in multiple consecutive stages. The plasma will be derived from gaseous targets, producing plasma densities slightly below the critical plasma density (underdense) for the driving laser. Such a plasma is experimentally robust, being repeatable and relatively transparent to externally injected ions from a previous stage. When optimized, multiple stages of this underdense laser plasma acceleration mechanism can progressively accelerate the ion...

Published

2017

9. Optical shaping of gas targets for laser plasma ion sources

Author

Zulfikar Najmudin, O. C. Ettlinger, Nicholas P. Dover, O. Tresca, C. Maharjan, Peter Shkolnikov, N. Cook, Mikhail Polyanskiy, Igor Pogorelsky, Engineering & Physical Science Research Council (E, and Science and Technology Facilities Council (STFC)

Subjects

Physics, Fluids & Plasmas, Particle accelerator, Plasma, Condensed Matter Physics, Laser, 01 natural sciences, 010305 fluids & plasmas, law.invention, Pulse (physics), Ion, Acceleration, 0202 Atomic, Molecular, Nuclear, Particle And Plasma Physics, law, 0103 physical sciences, Atomic physics, 010306 general physics, Energy (signal processing), Blast wave

Abstract

We report on the experimental demonstration of a technique to generate steep density gradients in gas-jet targets of interest to laser–plasma ion acceleration. By using an intentional low-energy prepulse, we generated a hydrodynamic blast wave in the gas to shape the target prior to the arrival of an intense CO$_{2}$ (${\it\lambda}\approx 10~{\rm\mu}\text{m}$) drive pulse. This technique has been recently shown to facilitate the generation of ion beams by shockwave acceleration (Tresca et al., Phys. Rev. Lett., vol. 115 (9), 2015, 094802). Here, we discuss and introduce a model to understand the generation of these blast waves and discuss in depth the experimental realisation of the technique, supported by hydrodynamics simulations. With appropriate prepulse energy and timing, this blast wave can generate steepened density gradients as short as $l\approx 20~{\rm\mu}\text{m}$ ($1/e$), opening up new possibilities for laser–plasma studies with near-critical gaseous targets.

Published

2016

10. Angularly resolved characterization of ion beams from laser-ultrathin foil interactions

Author

Marco Borghesi, Zulfikar Najmudin, Aaron Alejo, Domenico Doria, H. Padda, Paul McKenna, L Romagnani, Ross Gray, K. Naughton, Graeme Scott, Kristjan Poder, Hamad Ahmed, David Neely, D. R. Symes, C. Scullion, O. C. Ettlinger, G. Hicks, James Green, D. Jung, Satyabrata Kar, and Matthew Zepf

Subjects

Materials science, Spectrometer, business.industry, Laser, 01 natural sciences, Electron cyclotron resonance, 010305 fluids & plasmas, law.invention, Ion, Characterization (materials science), Optics, law, 0103 physical sciences, Cathode ray, 010306 general physics, business, Instrumentation, QC, Mathematical Physics, FOIL method, Beam (structure)

Abstract

Methods and techniques used to capture and analyze beam profiles produced from the interaction of intense, ultrashort laser pulses and ultrathin foil targets using stacks of Radiochromic Film (RCF) and Columbia Resin #39 (CR-39) are presented. The identification of structure in the beam is particularly important in this regime, as it may be indicative of the dominance of specific acceleration mechanisms. Additionally, RCF can be used to deconvolve proton spectra with coarse energy resolution while mantaining angular information across the whole beam.

Published

2016

11. Generation of intense quasi-electrostatic fields due to deposition of particles accelerated by petawatt-range laser-matter interactions

Author

T. Robinson, Roland Smith, E. J. Ditter, G. Hicks, Fabrizio Consoli, M. M. Notley, Zulfikar Najmudin, Samuel Giltrap, O. C. Ettlinger, R. De Angelis, Consoli, F., De Angelis, R., Robinson, T. S., Giltrap, S., Hicks, G. S., Ditter, E. J., Ettlinger, O. C., Najmudin, Z., Notley, M., Smith, R. A., Engineering & Physical Science Research Council (E, Science and Technology Facilities Council (STFC), Engineering & Physical Science Research Council (EPSRC), and Imperial College Trust

Subjects

0301 basic medicine, Field (physics), lcsh:Medicine, Article, law.invention, 03 medical and health sciences, 0302 clinical medicine, law, Electric field, lcsh:Science, Electromagnetic pulse, Physics, Range (particle radiation), Multidisciplinary, Spectrometer, Nuclear fusion and fission, lcsh:R, Laser-produced plasmas, Nanosecond, Laser, Electrical and electronic engineering, Magnetic field, Computational physics, Applied physics, 030104 developmental biology, lcsh:Q, Applied optics, 030217 neurology & neurosurgery

Abstract

We demonstrate here for the first time that charge emitted by laser-target interactions at petawatt peak-powers can be efficiently deposited on a capacitor-collector structure far away from the target and lead to the rapid (tens of nanoseconds) generation of large quasi-static electric fields over wide (tens-of-centimeters scale-length) regions, with intensities much higher than common ElectroMagnetic Pulses (EMPs) generated by the same experiment in the same position. A good agreement was obtained between measurements from a classical field-probe and calculations based on particle-flux measurements from a Thomson spectrometer. Proof-of-principle particle-in-cell simulations reproduced the measurements of field evolution in time, giving a useful insight into the charging process, generation and distribution of fields. The understanding of this charging phenomenon and of the related intense fields, which can reach the MV/m order and in specific configurations might also exceed it, is very important for present and future facilities studying laser-plasma-acceleration and inertial-confinement-fusion, but also for application to the conditioning of accelerated charged-particles, the generation of intense electric and magnetic fields and many other multidisciplinary high-power laser-driven processes.