Your search keyword '"Thomas AGR"' showing total 39 results

1. Physiological and subjective arousal to prospective mental imagery: A mechanism for behavioral change?

Author

Thomas Agren

Subjects

Medicine, Science

Published

2023

2. The influence of laser focusing conditions on the direct laser acceleration of electrons

Author

Tang, H, Tangtartharakul, K, Babjak, R, Yeh, I-L, Albert, F, Chen, H, Campbell, PT, Ma, Y, Nilson, PM, Russell, BK, Shaw, JL, Thomas, AGR, Vranic, M, Arefiev, AV, and Willingale, L

Subjects

Nuclear and Plasma Physics, Physical Sciences, Affordable and Clean Energy, direct laser acceleration, laser-plasma interaction, electron acceleration, Fluids & Plasmas, Physical sciences

Abstract

Direct laser acceleration of electrons during a high-energy, picosecond laser interaction with an underdense plasma has been demonstrated to be substantially enhanced by controlling the laser focusing geometry. Experiments using the OMEGA EP facility measured electrons accelerated to maximum energies exceeding 120 times the ponderomotive energy under certain laser focusing, pulse energy, and plasma density conditions. Two-dimensional particle-in-cell simulations show that the laser focusing conditions alter the laser field evolution, channel fields generation, and electron oscillation, all of which contribute to the final electron energies. The optimal laser focusing condition occurs when the transverse oscillation amplitude of the accelerated electron in the channel fields matches the laser beam width, resulting in efficient energy gain. Through this observation, a simple model was developed to calculate the optimal laser focal spot size in more general conditions and is validated by experimental data.

Published

2024

3. On the energy spectrum evolution of electrons undergoing radiation cooling

Author

Bulanov, SV, Grittani, GM, Shaisultanov, R, Esirkepov, TZ, Ridgers, CP, Bulanov, SS, Russell, BK, and Thomas, AGR

Subjects

Nuclear and Plasma Physics, Physical Sciences, Affordable and Clean Energy

Abstract

Radiative cooling of electron beams interacting with counter-propagating electromagnetic waves is analyzed, taking into account the quantum modification of the radiation friction force. Central attention is paid to the evolution of the energy spectrum of electrons accelerated by the laser wake field acceleration mechanism. As an electron beam loses energy to radiation, the mean energy decreases and the form of the energy distribution also changes due to quantum-mechanical spectral broadening.

Published

2024

4. Plasma-based particle sources

Author

Fuchs, M, Andonian, G, Apsimon, O, Büscher, M, Downer, MC, Filippetto, D, Lehrach, A, Schroeder, CB, Shadwick, BA, Thomas, AGR, Vafaei-Najafabadi, N, and Xia, G

Subjects

Nuclear and Plasma Physics, Synchrotrons and Accelerators, Physical Sciences, Affordable and Clean Energy, Engineering, Nuclear & Particles Physics, Physical sciences

Abstract

Abstract High-brightness particle beams generated by advanced accelerator concepts have the potential to become an essential part of future accelerator technology. In particular, high-gradient accelerators can generate and rapidly accelerate particle beams to relativistic energies. The rapid acceleration and strong confining fields can minimize irreversible detrimental effects to the beam brightness that occur at low beam energies, such as emittance growth or pulse elongation caused by space charge forces. Due to the high accelerating gradients, these novel accelerators are also significantly more compact than conventional technology. Advanced accelerators can be extremely variable and are capable of generating particle beams with vastly different properties using the same driver and setup with only modest changes to the interaction parameters. So far, efforts have mainly been focused on the generation of electron beams, but there are concepts to extend the sources to generate spin-polarized electron beams or positron beams. The beam parameters of these particle sources are largely determined by the injection and subsequent acceleration processes. Although, over the last decade there has been significant progress, the sources are still lacking a sufficiently high 6-dimensional (D) phase-space density that includes small transverse emittance, small energy spread and high charge, and operation at high repetition rate. This is required for future particle colliders with a sufficiently high luminosity or for more near-term applications, such as enabling the operation of free-electron lasers (FELs) in the X-ray regime. Major research and development efforts are required to address these limitations in order to realize these approaches for a front-end injector for a future collider or next-generation light sources. In particular, this includes methods to control and manipulate the phase-space and spin degrees-of-freedom of ultrashort plasma-based electron bunches with high accuracy, and methods that increase efficiency and repetition rate. These efforts also include the development of high-resolution diagnostics, such as full 6D phase-space measurements, beam polarimetry and high-fidelity simulation tools. A further increase in beam luminosity can be achieve through emittance damping. Emittance cooling via the emission of synchrotron radiation using current technology requires kilometer-scale damping rings. For future colliders, the damping rings might be replaced by a substantially more compact plasma-based approach. Here, plasma wigglers with significantly stronger magnetic fields are used instead of permanent-magnet based wigglers to achieve similar damping performance but over a two orders of magnitude reduced length.

Published

2024

5. The science case for an intermediate energy advanced and novel accelerator linear collider facility

Author

Bulanov, SS, Aidala, CA, Benedetti, C, Bernstein, R, Esarey, E, Geddes, CGR, Gessner, SJ, Gonsalves, AJ, Hogan, MJ, Jacobs, PM, Jing, C, Knapen, S, Lee, C, Low, I, Lu, X, Meade, P, Muggli, P, Musumeci, P, Nachman, B, Nakamura, K, Nelson, T, Griso, S Pagan, Palmer, M, Prebys, E, Schroeder, CB, Shiltsev, V, Terzani, D, Thomas, AGR, van Tilborg, J, Turner, M, Vafaei-Najafabadi, N, Visinelli, L, Yao, W-M, and Yoshida, R

Subjects

Nuclear and Plasma Physics, Particle and High Energy Physics, Physical Sciences, Accelerator Applications, Accelerator Subsystems and Technologies, Wake-field acceleration (laser-driven, electron-driven), ATAP-GENERAL, ATAP-BELLA Center, ATAP-2024, Engineering, Nuclear & Particles Physics, Physical sciences

Abstract

It is widely accepted that the next lepton collider beyond a Higgs factory would require center-of-mass energy of the order of up to 15 TeV. Since, given reasonable space and cost restrictions, conventional accelerator technology reaches its limits near this energy, high-gradient advanced acceleration concepts are attractive. Advanced and novel accelerators (ANAs) are leading candidates due to their ability to produce acceleration gradients on the order of 1-100 GV/m, leading to compact acceleration facilities. However, intermediate energy facilities (IEF) are required to test the critical technology elements on the way towards multi-TeV-class collliders. Here a science case for a 20-100 GeV center-of-mass energy ANA-based lepton collider that can be a candidate for an intermediate energy facility is presented. The IEF can provide numerous opportunities for high energy physics studies including precision Quantum Chromodynamics and Beyond the Standard Model physics measurements, investigation of charged particle interactions with extreme electromagnetic fields, and exploring muon and proton beam acceleration. Possible applications of this collider include the studies of γγ and electron beam-fixed target/beamdump collider designs. Thus, the goal of the proposed IEF is to both carry out particle physics measurements in the 20-100 GeV ranges as well as to serve as an ANA demonstrator facility.

Published

2024

6. 2020 roadmap on plasma accelerators

Author

Albert, F, Couprie, ME, Debus, A, Downer, MC, Faure, J, Flacco, A, Gizzi, LA, Grismayer, T, Huebl, A, Joshi, C, Labat, M, Leemans, WP, Maier, AR, Mangles, SPD, Mason, P, Mathieu, F, Muggli, P, Nishiuchi, M, Osterhoff, J, Rajeev, PP, Schramm, U, Schreiber, J, Thomas, AGR, Vay, JL, Vranic, M, and Zeil, K

Subjects

plasma accelerators, laser&#8211, plasma interactions, laser wakefield acceleration, particle beams, strong field QED, free electron lasers, Fluids & Plasmas, Physical Sciences

Abstract

Plasma-based accelerators use the strong electromagnetic fields that can be supported by plasmas to accelerate charged particles to high energies. Accelerating field structures in plasma can be generated by powerful laser pulses or charged particle beams. This research field has recently transitioned from involving a few small-scale efforts to the development of national and international networks of scientists supported by substantial investment in large-scale research infrastructure. In this New Journal of Physics 2020 Plasma Accelerator Roadmap, perspectives from experts in this field provide a summary overview of the field and insights into the research needs and developments for an international audience of scientists, including graduate students and researchers entering the field.

Published

2021

7. Relativistic plasma physics in supercritical fields

Author

Zhang, P, Bulanov, SS, Seipt, D, Arefiev, AV, and Thomas, AGR

Subjects

physics.plasm-ph, hep-ph, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Classical Physics, Fluids & Plasmas

Abstract

Since the invention of chirped pulse amplification, which was recognized by a Nobel Prize in physics in 2018, there has been a continuing increase in available laser intensity. Combined with advances in our understanding of the kinetics of relativistic plasma, studies of laser-plasma interactions are entering a new regime where the physics of relativistic plasmas is strongly affected by strong-field quantum electrodynamics (QED) processes, including hard photon emission and electron-positron (e-e+) pair production. This coupling of quantum emission processes and relativistic collective particle dynamics can result in dramatically new plasma physics phenomena, such as the generation of dense e-e+ pair plasma from near vacuum, complete laser energy absorption by QED processes, or the stopping of an ultra-relativistic electron beam, which could penetrate a cm of lead, by a hair's breadth of laser light. In addition to being of fundamental interest, it is crucial to study this new regime to understand the next generation of ultra-high intensity laser-matter experiments and their resulting applications, such as high energy ion, electron, positron, and photon sources for fundamental physics studies, medical radiotherapy, and next generation radiography for homeland security and industry.

Published

2020

8. On the design of experiments to study extreme field limits

Author

Bulanov, SS, Chen, M, Schroeder, CB, Esarey, E, Leemans, WP, Bulanov, SV, Esirkepov, T Zh, Kando, M, Koga, JK, Zhidkov, AG, Chen, P, Mur, VD, Narozhny, NB, Popov, VS, Thomas, AGR, and Korn, G

Subjects

Radiation damping, Quantum Electrodynamics, Electron-positron avalanches, physics.plasm-ph, hep-ph

Abstract

We propose experiments on the collision of high intensity electromagnetic pulses with electron bunches and on the collision of multiple electromagnetic pulses for studying extreme field limits in the nonlinear interaction of electromagnetic waves. The effects of nonlinear QED will be revealed in these laser plasma experiments. © 2012 American Institute of Physics.

Published

2012

9. Numerical calculations of a high brilliance synchrotron source and on issues with characterizing strong radiation damping effects in non-linear Thomson/Compton backscattering experiments

Author

Thomas, AGR, Ridgers, CP, Bulanov, SS, Griffin, BJ, and Mangles, SPD

Subjects

physics.acc-ph, physics.optics, physics.plasm-ph

Abstract

A number of theoretical calculations have studied the effect of radiationreaction forces on radiation distributions in strong field counter-propagatingelectron beam-laser interactions, but could these effects - including quantumcorrections - be observed in interactions with realistic bunches and focusingfields, as is hoped in a number of soon to be proposed experiments? We presentnumerical calculations of the angularly resolved radiation spectrum from anelectron bunch with parameters similar to those produced in laser wakefieldacceleration experiments, interacting with an intense, ultrashort laser pulse.For our parameters, the effects of radiation damping on the angulardistribution and energy distribution of \emph{photons} is not easilydiscernible for a "realistic" moderate emittance electron beam. However,experiments using such a counter-propagating beam-laser geometry should be ableto measure such effects using current laser systems through measurement of the\emph{electron beam} properties. In addition, the brilliance of this source isvery high, with peak spectral brilliance exceeding $10^{29}$photons$\,$s$^{-1}$mm$^{-2}$mrad$^{-2}(0.1$% bandwidth$)^{-1}$ withapproximately 2% efficiency and with a peak energy of 10 MeV.

Published

2012

10. Laser acceleration of protons from near critical density targets for application to radiation therapy

Author

Bulanov, SS, Litzenberg, DW, Pirozhkov, AS, Thomas, AGR, Willingale, L, Krushelnick, K, and Maksimchuk, A

Subjects

physics.plasm-ph

Abstract

Laser accelerated protons can be a complimentary source for treatment ofoncological diseases to the existing hadron therapy facilities. We demonstratehow the protons, accelerated from near-critical density plasmas by laser pulseshaving relatively small power, reach energies which may be of interest formedical applications. When an intense laser pulse interacts with near-criticaldensity plasma it makes a channel both in the electron and then in the iondensity. The propagation of a laser pulse through such a self-generated channelis connected with the acceleration of electrons in the wake of a laser pulseand generation of strong moving electric and magnetic fields in the propagationchannel. Upon exiting the plasma the magnetic field generates a quasi-staticelectric field that accelerates and collimates ions from a thin filament formedin the propagation channel. Two-dimensional Particle-in-Cell simulations showthat a 100 TW laser pulse tightly focused on a near-critical density target isable to accelerate protons up to energy of 250 MeV. Scaling laws and optimalconditions for proton acceleration are established considering the energydepletion of the laser pulse.

Published

2010

11. A Bright Spatially-Coherent Compact X-ray Synchrotron Source

Author

Kneip, S, McGuffey, C, Martins, JL, Martins, SF, Bellei, C, Chvykov, V, Dollar, F, Fonseca, R, Huntington, C, Kalintchenko, G, Maksimchuk, A, Mangles, SPD, Matsuoka, T, Nagel, SR, Palmer, C, Schreiber, J, Phuoc, K Ta, Thomas, AGR, Yanovsky, V, Silva, LO, Krushelnick, K, and Najmudin, Z

Subjects

physics.plasm-ph, physics.acc-ph

Abstract

Each successive generation of x-ray machines has opened up new frontiers inscience, such as the first radiographs and the determination of the structureof DNA. State-of-the-art x-ray sources can now produce coherent high brightnesskeV x-rays and promise a new revolution in imaging complex systems on nanometreand femtosecond scales. Despite the demand, only a few dedicated synchrotronfacilities exist worldwide, partially due the size and cost of conventional(accelerator) technology. Here we demonstrate the use of a recently developedcompact laser-plasma accelerator to produce a well-collimated,spatially-coherent, intrinsically ultrafast source of hard x-rays. This methodreduces the size of the synchrotron source from the tens of metres tocentimetre scale, accelerating and wiggling a high electron chargesimultaneously. This leads to a narrow-energy spread electron beam and x-raysource that is >1000 times brighter than previously reported plasma wiggler andthus has the potential to facilitate a myriad of uses across the whole spectrumof light-source applications.

Published

2009

12. Laser acceleration of protons from near critical density targets for application to radiation therapy

Author

Bulanov, SS, Litzenberg, DW, Pirozhkov, AS, Thomas, AGR, Willingale, L, Krushelnick, K, Maksimchuk, A, Bulanov, SS, Litzenberg, DW, Pirozhkov, AS, Thomas, AGR, Willingale, L, Krushelnick, K, and Maksimchuk, A

Abstract

Laser accelerated protons can be a complimentary source for treatment of oncological diseases to the existing hadron therapy facilities. We demonstrate how the protons, accelerated from near-critical density plasmas by laser pulses having relatively small power, reach energies which may be of interest for medical applications. When an intense laser pulse interacts with near-critical density plasma it makes a channel both in the electron and then in the ion density. The propagation of a laser pulse through such a self-generated channel is connected with the acceleration of electrons in the wake of a laser pulse and generation of strong moving electric and magnetic fields in the propagation channel. Upon exiting the plasma the magnetic field generates a quasi-static electric field that accelerates and collimates ions from a thin filament formed in the propagation channel. Two-dimensional Particle-in-Cell simulations show that a 100 TW laser pulse tightly focused on a near-critical density target is able to accelerate protons up to energy of 250 MeV. Scaling laws and optimal conditions for proton acceleration are established considering the energy depletion of the laser pulse.

Published

2017

13. Laser-driven generation of collimated ultra-relativistic positron beams

Author

Sarri, Gianluca, Schumaker, W, Di Piazza, A, Poder, K, Cole, JM, Vargas, M, Doria, Domenico, Kushel, S, Dromey, Brendan, Grittani, G, Gizzi, L, Dieckmann, Mark Eric, Green, A, Chvykov, V, Maksimchuk, A, Yanovsky, V, He, ZH, Hou, BX, Nees, JA, Kar, S, Najmudin, Z, Thomas, AGR, Keitel, CH, Krushelnick, K, Zepf, Matt, Sarri, Gianluca, Schumaker, W, Di Piazza, A, Poder, K, Cole, JM, Vargas, M, Doria, Domenico, Kushel, S, Dromey, Brendan, Grittani, G, Gizzi, L, Dieckmann, Mark Eric, Green, A, Chvykov, V, Maksimchuk, A, Yanovsky, V, He, ZH, Hou, BX, Nees, JA, Kar, S, Najmudin, Z, Thomas, AGR, Keitel, CH, Krushelnick, K, and Zepf, Matt

Abstract

We report on recent experimental results concerning the generation of collimated (divergence of the order of a few mrad) ultra-relativistic positron beams using a fully optical system. The positron beams are generated exploiting a quantum-electrodynamic cascade initiated by the propagation of a laser-accelerated, ultra-relativistic electron beam through high-Z solid targets. As long as the target thickness is comparable to or smaller than the radiation length of the material, the divergence of the escaping positron beam is of the order of the inverse of its Lorentz factor. For thicker solid targets the divergence is seen to gradually increase, due to the increased number of fundamental steps in the cascade, but it is still kept of the order of few tens of mrad, depending on the spectral components in the beam. This high degree of collimation will be fundamental for further injection into plasma-wakefield afterburners.

Published

2013

14. Laser-wakefield acceleration of monoenergetic electron beams in the first plasma-wave period

Author

Mangles, SPD, Thomas, AGR, Kaluza, MC, Lundh, Olle, Lindau, Filip, Persson, Anders, Tsung, FS, Najmudin, Z, Mori, WB, Wahlström, Claes-Göran, Krushelnick, K, Mangles, SPD, Thomas, AGR, Kaluza, MC, Lundh, Olle, Lindau, Filip, Persson, Anders, Tsung, FS, Najmudin, Z, Mori, WB, Wahlström, Claes-Göran, and Krushelnick, K

Abstract

Beam profile measurements of laser-wakefield accelerated electron bunches reveal that in the monoenergetic regime the electrons are injected and accelerated at the back of the first period of the plasma wave. With pulse durations c tau >=lambda(p), we observe an elliptical beam profile with the axis of the ellipse parallel to the axis of the laser polarization. This increase in divergence in the laser polarization direction indicates that the electrons are accelerated within the laser pulse. Reducing the plasma density (decreasing c tau/lambda(p)) leads to a beam profile with less ellipticity, implying that the self-injection occurs at the rear of the first period of the plasma wave. This also demonstrates that the electron bunches are less than a plasma wavelength long, i.e., have a duration < 25 fs. This interpretation is supported by 3D particle-in-cell simulations.

Published

2006

15. Disruption of Memory Reconsolidation Erases a Fear Memory Trace in the Human Amygdala: An 18-Month Follow-Up.

Author

Johannes Björkstrand, Thomas Agren, Andreas Frick, Jonas Engman, Elna-Marie Larsson, Tomas Furmark, and Mats Fredrikson

Subjects

Medicine, Science

Abstract

Fear memories can be attenuated by reactivation followed by disrupted reconsolidation. Using functional magnetic resonance imaging we recently showed that reactivation and reconsolidation of a conditioned fear memory trace in the basolateral amygdala predicts subsequent fear expression over two days, while reactivation followed by disrupted reconsolidation abolishes the memory trace and suppresses fear. In this follow-up study we demonstrate that the behavioral effect persists over 18 months reflected in superior reacquisition after undisrupted, as compared to disrupted reconsolidation, and that neural activity in the basolateral amygdala representing the initial fear memory predicts return of fear. We conclude that disrupting reconsolidation have long lasting behavioral effects and may permanently erase the fear component of an amygdala-dependent memory.

Published

2015

16. Single-Shot Diagnosis of Electron Energy Evolution via Streaked Betatron X Rays in a Curved Laser Wakefield Accelerator.

Author

Ma Y, Cardarelli JA, Campbell PT, Fourmaux S, Fitzgarrald R, Balcazar MD, Antoine AF, Beier NF, Qian Q, Hussein AE, Kettle B, Klein SR, Krushelnick K, Li YF, Mangles SPD, Sarri G, Seipt D, Senthilkumaran V, Streeter MJV, Willingale L, and Thomas AGR

Abstract

We report on an experimental observation of the streaking of betatron x rays in a curved laser wakefield accelerator. The streaking of the betatron x rays was realized by launching a laser pulse into a plasma with a transverse density gradient. By controlling the plasma density and the density gradient, we realized the steering of the laser driver, electron beam, and betatron x rays simultaneously. Moreover, we observed an energy-angle correlation of the streaked betatron x rays and utilized it in diagnosing the electron acceleration process in a single-shot mode. Our work could also find applications in advanced control of laser beam and particle propagation. More importantly, the angular streaked betatron x ray has an intrinsic spatiotemporal correlation, which makes it a promising tool for single-shot pump-probe applications.

Published

2024

17. Narrow bandwidth, low-emittance positron beams from a laser-wakefield accelerator.

Author

Streeter MJV, Colgan C, Carderelli J, Ma Y, Cavanagh N, Los EE, Ahmed H, Antoine AF, Audet T, Balcazar MD, Calvin L, Kettle B, Mangles SPD, Najmudin Z, Rajeev PP, Symes DR, Thomas AGR, and Sarri G

Abstract

The rapid progress that plasma wakefield accelerators are experiencing is now posing the question as to whether they could be included in the design of the next generation of high-energy electron-positron colliders. However, the typical structure of the accelerating wakefields presents challenging complications for positron acceleration. Despite seminal proof-of-principle experiments and theoretical proposals, experimental research in plasma-based acceleration of positrons is currently limited by the scarcity of positron beams suitable to seed a plasma accelerator. Here, we report on the first experimental demonstration of a laser-driven source of ultra-relativistic positrons with sufficient spectral and spatial quality to be injected in a plasma accelerator. Our results indicate, in agreement with numerical simulations, selection and transport of positron beamlets containing N e + ≥ 10 5 positrons in a 5% bandwidth around 600 MeV, with femtosecond-scale duration and micron-scale normalised emittance. Particle-in-cell simulations show that positron beams of this kind can be guided and accelerated in a laser-driven plasma accelerator, with favourable scalings to further increase overall charge and energy using PW-scale lasers. The results presented here demonstrate the possibility of performing experimental studies of positron acceleration in a laser-driven wakefield accelerator., (© 2024. The Author(s).)

Published

2024

18. Dephasingless plasma wakefield photon acceleration.

Author

Sandberg R and Thomas AGR

Abstract

Sandberg and Thomas [Phys. Rev. Lett. 130, 085001 (2023)0031-900710.1103/PhysRevLett.130.085001] proposed a scheme to generate ultrashort, high-energy pulses of XUV photons though dephasingless photon acceleration in a beam-driven plasma wakefield. An ultrashort laser pulse is placed in the plasma wake behind a relativistic electron bunch such that it experiences a comoving negative density gradient and therefore shifts up in frequency. Using a tapered density profile provides phase-matching between driver and witness pulses. In this paper, we give the details of the wakefield solutions and phase-matching conditions used to generate the phase-matching density profile. The short, high-density, and weak driver limits are considered. We show, explicitly, the numerical algorithm used to calculate the density profiles.

Published

2024

19. Observation of Monoenergetic Electrons from Two-Pulse Ionization Injection in Quasilinear Laser Wakefields.

Author

von der Leyen MW, Holloway J, Ma Y, Campbell PT, Aboushelbaya R, Qian Q, Antoine AF, Balcazar M, Cardarelli J, Feng Q, Fitzgarrald R, Hou BX, Kalinchenko G, Latham J, Maksimchuk AM, McKelvey A, Nees J, Ouatu I, Paddock RW, Spiers B, Thomas AGR, Timmis R, Krushelnick K, and Norreys PA

Abstract

The generation of low emittance electron beams from laser-driven wakefields is crucial for the development of compact x-ray sources. Here, we show new results for the injection and acceleration of quasimonoenergetic electron beams in low amplitude wakefields experimentally and using simulations. This is achieved by using two laser pulses decoupling the wakefield generation from the electron trapping via ionization injection. The injection duration, which affects the beam charge and energy spread, is found to be tunable by adjusting the relative pulse delay. By changing the polarization of the injector pulse, reducing the ionization volume, the electron spectra of the accelerated electron bunches are improved.

Published

2023

20. Photon Acceleration from Optical to XUV.

Author

Sandberg RT and Thomas AGR

Abstract

The propagating density gradients of a plasma wakefield may frequency upshift a trailing witness laser pulse, a process known as "photon acceleration." In uniform plasma, the witness laser will eventually dephase because of group delay. We find phase-matching conditions for the pulse using a tailored density profile. An analytic solution for a 1D nonlinear plasma wake with an electron beam driver indicates that, even though the plasma density decreases, the frequency shift reaches no asymptotic limit, i.e., is unlimited provided the wake can be sustained. In fully self-consistent 1D particle-in-cell (PIC) simulations, more than 40 times frequency shifts were demonstrated. In quasi-3D PIC simulations, frequency shifts up to 10 times were observed, limited only by simulation resolution and nonoptimized driver evolution. The pulse energy increases in this process, by a factor of 5, and the pulse is guided and temporally compressed by group velocity dispersion, resulting in the resulting extreme ultraviolet laser pulse having near-relativistic (a&#95;{0}∼0.4) intensity.

Published

2023

21. Optimization of the electron beam dump for a GeV-class laser electron accelerator.

Author

Shi T, Sun D, Jovanovic I, Kalinchenko G, Krushelnick K, Kuranz CC, Maksimchuk A, Nees J, Thomas AGR, and Willingale L

Abstract

The advances of laser-driven electron acceleration offer the promise of great reductions in the size of high-energy electron accelerator facilities. Accordingly, it is desirable to design compact radiation shielding for such facilities. A key component of radiation shielding is the high-energy electron beam dump. In an effort to optimize the electron beam dump design, different material combinations have been simulated with the FLUKA Monte Carlo code in the range of 1-40 GeV. The studied beam dump configurations consist of alternating layers of high-Z material (lead or iron) and low-Z material (high-density concrete or borated polyethylene) in either three-layer or five-layer structures. The designs of various beam dump configuration have been compared and it has been found that the iron and concrete stacking in a three-layer structure with a thick iron layer results in the lowest dose at 1, 10, and 40 GeV. The performance of the beam dump exhibits a strong dependence on the selected materials, the stacking method, the beam dump thickness, as well as the electron energy. This parametric study provides general insights that can be used for compact shielding design of future electron accelerator facilities., (Copyright © 2021. Published by Elsevier Ltd.)

Published

2021

22. Observations of pressure anisotropy effects within semi-collisional magnetized plasma bubbles.

Author

Tubman ER, Joglekar AS, Bott AFA, Borghesi M, Coleman B, Cooper G, Danson CN, Durey P, Foster JM, Graham P, Gregori G, Gumbrell ET, Hill MP, Hodge T, Kar S, Kingham RJ, Read M, Ridgers CP, Skidmore J, Spindloe C, Thomas AGR, Treadwell P, Wilson S, Willingale L, and Woolsey NC

Abstract

Magnetized plasma interactions are ubiquitous in astrophysical and laboratory plasmas. Various physical effects have been shown to be important within colliding plasma flows influenced by opposing magnetic fields, however, experimental verification of the mechanisms within the interaction region has remained elusive. Here we discuss a laser-plasma experiment whereby experimental results verify that Biermann battery generated magnetic fields are advected by Nernst flows and anisotropic pressure effects dominate these flows in a reconnection region. These fields are mapped using time-resolved proton probing in multiple directions. Various experimental, modelling and analytical techniques demonstrate the importance of anisotropic pressure in semi-collisional, high-β plasmas, causing a reduction in the magnitude of the reconnecting fields when compared to resistive processes. Anisotropic pressure dynamics are crucial in collisionless plasmas, but are often neglected in collisional plasmas. We show pressure anisotropy to be essential in maintaining the interaction layer, redistributing magnetic fields even for semi-collisional, high energy density physics (HEDP) regimes.

Published

2021

23. Automation and control of laser wakefield accelerators using Bayesian optimization.

Author

Shalloo RJ, Dann SJD, Gruse JN, Underwood CID, Antoine AF, Arran C, Backhouse M, Baird CD, Balcazar MD, Bourgeois N, Cardarelli JA, Hatfield P, Kang J, Krushelnick K, Mangles SPD, Murphy CD, Lu N, Osterhoff J, Põder K, Rajeev PP, Ridgers CP, Rozario S, Selwood MP, Shahani AJ, Symes DR, Thomas AGR, Thornton C, Najmudin Z, and Streeter MJV

Abstract

Laser wakefield accelerators promise to revolutionize many areas of accelerator science. However, one of the greatest challenges to their widespread adoption is the difficulty in control and optimization of the accelerator outputs due to coupling between input parameters and the dynamic evolution of the accelerating structure. Here, we use machine learning techniques to automate a 100 MeV-scale accelerator, which optimized its outputs by simultaneously varying up to six parameters including the spectral and spatial phase of the laser and the plasma density and length. Most notably, the model built by the algorithm enabled optimization of the laser evolution that might otherwise have been missed in single-variable scans. Subtle tuning of the laser pulse shape caused an 80% increase in electron beam charge, despite the pulse length changing by just 1%.

Published

2020

24. Towards isolated attosecond electron bunches using ultrashort-pulse laser-solid interactions.

Author

Lin J, Batson T, Nees J, Thomas AGR, and Krushelnick K

Abstract

We investigate MeV-level attosecond electron bunches from ultrashort-pulse laser-solid interactions through similarities between experimental and simulated electron energy spectra. We show measurements of the bunch duration and temporal structure from particle-in-cell simulations. The experimental observation of such bunches favors specular reflection direction when focusing the laser pulse onto a subwavelength boundary of thick overdense plasmas at grazing incidence. Particle-in-cell simulation further reveals that the attosecond duration is a result of ultra-thin ([Formula: see text]tenth of a micron) gaps of zero electromagnetic energy density in the modulated reflected radiation, while the bunching (locally peaked electron concentration) comes from the highly-directional electron angular distribution acquired by the electrons in a grazing incidence setup. To isolate a single electron bunch, we perform simulations using 1-cycle laser pulses and analyze the effect of carrier-envelop phase with particle tracking. The duration of the electron bunch can be further decreased by increasing the laser intensity and the focal spot size, while its direction can be changed by tuning the preplasma density gradient.

Published

2020

25. Magnetic Signatures of Radiation-Driven Double Ablation Fronts.

Author

Campbell PT, Walsh CA, Russell BK, Chittenden JP, Crilly A, Fiksel G, Nilson PM, Thomas AGR, Krushelnick K, and Willingale L

Abstract

In experiments performed with the OMEGA EP laser system, magnetic field generation in double ablation fronts was observed. Proton radiography measured the strength, spatial profile, and temporal dynamics of self-generated magnetic fields as the target material was varied between plastic, aluminum, copper, and gold. Two distinct regions of magnetic field are generated in mid-Z targets-one produced by gradients from electron thermal transport and the second from radiation-driven gradients. Extended magnetohydrodynamic simulations including radiation transport reproduced key aspects of the experiment, including field generation and double ablation front formation.

Published

2020

26. Sarri et al. Reply.

Author

Sarri G, Schumaker W, Di Piazza A, Vargas M, Dromey B, Dieckmann ME, Chvykov V, Maksimchuk A, Yanovsky V, He ZH, Hou BX, Nees JA, Thomas AGR, Keitel CH, Zepf M, and Krushelnick K

Published

2020

27. Polarization-Dependent Self-Injection by Above Threshold Ionization Heating in a Laser Wakefield Accelerator.

Author

Ma Y, Seipt D, Hussein AE, Hakimi S, Beier NF, Hansen SB, Hinojosa J, Maksimchuk A, Nees J, Krushelnick K, Thomas AGR, and Dollar F

Abstract

We report on the experimental observation of a decreased self-injection threshold by using laser pulses with circular polarization in laser wakefield acceleration experiments in a nonpreformed plasma, compared to the usually employed linear polarization. A significantly higher electron beam charge was also observed for circular polarization compared to linear polarization over a wide range of parameters. Theoretical analysis and quasi-3D particle-in-cell simulations reveal that the self-injection and hence the laser wakefield acceleration is polarization dependent and indicate a different injection mechanism for circularly polarized laser pulses, originating from larger momentum gain by electrons during above threshold ionization. This enables electrons to meet the trapping condition more easily, and the resulting higher plasma temperature was confirmed via spectroscopy of the XUV plasma emission.

Published

2020

28. Author Correction: Laser-wakefield accelerators for high-resolution X-ray imaging of complex microstructures.

Author

Hussein AE, Senabulya N, Ma Y, Streeter MJV, Kettle B, Dann SJD, Albert F, Bourgeois N, Cipiccia S, Cole JM, Finlay O, Gerstmayr E, González IG, Higginbotham A, Jaroszynski DA, Falk K, Krushelnick K, Lemos N, Lopes NC, Lumsdon C, Lundh O, Mangles SPD, Najmudin Z, Rajeev PP, Schlepütz CM, Shahzad M, Smid M, Spesyvtsev R, Symes DR, Vieux G, Willingale L, Wood JC, Shahani AJ, and Thomas AGR

Abstract

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

29. Single-Shot Multi-keV X-Ray Absorption Spectroscopy Using an Ultrashort Laser-Wakefield Accelerator Source.

Author

Kettle B, Gerstmayr E, Streeter MJV, Albert F, Baggott RA, Bourgeois N, Cole JM, Dann S, Falk K, Gallardo González I, Hussein AE, Lemos N, Lopes NC, Lundh O, Ma Y, Rose SJ, Spindloe C, Symes DR, Šmíd M, Thomas AGR, Watt R, and Mangles SPD

Abstract

Single-shot absorption measurements have been performed using the multi-keV x rays generated by a laser-wakefield accelerator. A 200 TW laser was used to drive a laser-wakefield accelerator in a mode which produced broadband electron beams with a maximum energy above 1 GeV and a broad divergence of ≈15  mrad FWHM. Betatron oscillations of these electrons generated 1.2±0.2×10^{6}  photons/eV in the 5 keV region, with a signal-to-noise ratio of approximately 300∶1. This was sufficient to allow high-resolution x-ray absorption near-edge structure measurements at the K edge of a titanium sample in a single shot. We demonstrate that this source is capable of single-shot, simultaneous measurements of both the electron and ion distributions in matter heated to eV temperatures by comparison with density functional theory simulations. The unique combination of a high-flux, large bandwidth, few femtosecond duration x-ray pulse synchronized to a high-power laser will enable key advances in the study of ultrafast energetic processes such as electron-ion equilibration.

Published

2019

30. Adaptive control of laser-wakefield accelerators driven by mid-IR laser pulses.

Author

Lin J, Ma Y, Schwartz R, Woodbury D, Nees JA, Mathis M, Thomas AGR, Krushelnick K, and Milchberg H

Abstract

There has been growing interest both in studying high intensity ultrafast laser plasma interactions with adaptive control systems as well as using long wavelength driver beams. We demonstrate the coherent control of the dynamics of laser-wakefield acceleration driven by ultrashort (∼ 100 fs) mid-infrared (∼ 3.9 μm) laser pulses. The critical density at this wavelength is 7.3 × 10 19 cm -3 , which is achievable with an ordinary gas target system. Interactions between mid-infrared laser pulses and such near-critical-density plasma may be beneficial due to much higher absorption of laser energy. In addition, the normalized vector potential of the laser field a 0 increases with longer laser wavelength, lowering the required peak laser intensity to drive non-linear laser-wakefield acceleration. Here, MeV level, collimated electron beams with non-thermal, peaked energy spectra are generated. Optimization of electron beam qualities are realized through adaptive control of the laser wavefront. A genetic algorithm controlling a deformable mirror improves the electron total charge, energy spectra, beam pointing and stability at various plasma density profiles. Particle-in-cell simulations reveal that the optimal wavefront causes an earlier injection on the density up-ramp and thus higher energy gain as well as less filamentation during the interaction, which leads to the improvement in electron beam collimation and energy spectra.

Published

2019

31. Laser-wakefield accelerators for high-resolution X-ray imaging of complex microstructures.

Author

Hussein AE, Senabulya N, Ma Y, Streeter MJV, Kettle B, Dann SJD, Albert F, Bourgeois N, Cipiccia S, Cole JM, Finlay O, Gerstmayr E, González IG, Higginbotham A, Jaroszynski DA, Falk K, Krushelnick K, Lemos N, Lopes NC, Lumsdon C, Lundh O, Mangles SPD, Najmudin Z, Rajeev PP, Schlepütz CM, Shahzad M, Smid M, Spesyvtsev R, Symes DR, Vieux G, Willingale L, Wood JC, Shahani AJ, and Thomas AGR

Abstract

Laser-wakefield accelerators (LWFAs) are high acceleration-gradient plasma-based particle accelerators capable of producing ultra-relativistic electron beams. Within the strong focusing fields of the wakefield, accelerated electrons undergo betatron oscillations, emitting a bright pulse of X-rays with a micrometer-scale source size that may be used for imaging applications. Non-destructive X-ray phase contrast imaging and tomography of heterogeneous materials can provide insight into their processing, structure, and performance. To demonstrate the imaging capability of X-rays from an LWFA we have examined an irregular eutectic in the aluminum-silicon (Al-Si) system. The lamellar spacing of the Al-Si eutectic microstructure is on the order of a few micrometers, thus requiring high spatial resolution. We present comparisons between the sharpness and spatial resolution in phase contrast images of this eutectic alloy obtained via X-ray phase contrast imaging at the Swiss Light Source (SLS) synchrotron and X-ray projection microscopy via an LWFA source. An upper bound on the resolving power of 2.7 ± 0.3 μm of the LWFA source in this experiment was measured. These results indicate that betatron X-rays from laser wakefield acceleration can provide an alternative to conventional synchrotron sources for high resolution imaging of eutectics and, more broadly, complex microstructures.

Published

2019

32. A spectrometer for ultrashort gamma-ray pulses with photon energies greater than 10 MeV.

Author

Behm KT, Cole JM, Joglekar AS, Gerstmayr E, Wood JC, Baird CD, Blackburn TG, Duff M, Harvey C, Ilderton A, Kuschel S, Mangles SPD, Marklund M, McKenna P, Murphy CD, Najmudin Z, Poder K, Ridgers CP, Sarri G, Samarin GM, Symes D, Warwick J, Zepf M, Krushelnick K, and Thomas AGR

Abstract

We present a design for a pixelated scintillator based gamma-ray spectrometer for non-linear inverse Compton scattering experiments. By colliding a laser wakefield accelerated electron beam with a tightly focused, intense laser pulse, gamma-ray photons up to 100 MeV energies and with few femtosecond duration may be produced. To measure the energy spectrum and angular distribution, a 33 × 47 array of cesium-iodide crystals was oriented such that the 47 crystal length axis was parallel to the gamma-ray beam and the 33 crystal length axis was oriented in the vertical direction. Using an iterative deconvolution method similar to the YOGI code, modeling of the scintillator response using GEANT4 and fitting to a quantum Monte Carlo calculated photon spectrum, we are able to extract the gamma ray spectra generated by the inverse Compton interaction.

Published

2018

33. Ultrafast Imaging of Laser Driven Shock Waves using Betatron X-rays from a Laser Wakefield Accelerator.

Author

Wood JC, Chapman DJ, Poder K, Lopes NC, Rutherford ME, White TG, Albert F, Behm KT, Booth N, Bryant JSJ, Foster PS, Glenzer S, Hill E, Krushelnick K, Najmudin Z, Pollock BB, Rose S, Schumaker W, Scott RHH, Sherlock M, Thomas AGR, Zhao Z, Eakins DE, and Mangles SPD

Abstract

Betatron radiation from laser wakefield accelerators is an ultrashort pulsed source of hard, synchrotron-like x-ray radiation. It emanates from a centimetre scale plasma accelerator producing GeV level electron beams. In recent years betatron radiation has been developed as a unique source capable of producing high resolution x-ray images in compact geometries. However, until now, the short pulse nature of this radiation has not been exploited. This report details the first experiment to utilize betatron radiation to image a rapidly evolving phenomenon by using it to radiograph a laser driven shock wave in a silicon target. The spatial resolution of the image is comparable to what has been achieved in similar experiments at conventional synchrotron light sources. The intrinsic temporal resolution of betatron radiation is below 100 fs, indicating that significantly faster processes could be probed in future without compromising spatial resolution. Quantitative measurements of the shock velocity and material density were made from the radiographs recorded during shock compression and were consistent with the established shock response of silicon, as determined with traditional velocimetry approaches. This suggests that future compact betatron imaging beamlines could be useful in the imaging and diagnosis of high-energy-density physics experiments.

Published

2018

34. Diagnosis of warm dense conditions in foil targets heated by intense femtosecond laser pulses using Kα imaging spectroscopy.

Author

Bae LJ, Zastrau U, Chung HK, Bernstein AC, Cho MS, Dyer GM, Galtier E, He ZH, Heimann PA, Kang GB, Kim M, Kim YH, Lee HJ, Lee JW, Nagler B, Thomas AGR, and Cho BI

Abstract

Warm dense conditions in titanium foils irradiated with intense femtosecond laser pulses are diagnosed using an x-ray imaging spectroscopy technique. The line shapes of radially resolved titanium Kα spectra are measured with a toroidally bent GaAs crystal and an x-ray charge-coupled device. Measured spectra are compared with the K-shell emissions modeled using an atomic kinetics - spectroscopy simulation code. Kα line shapes are strongly affected by warm (5-40 eV) bulk electron temperatures and imply multiple temperature distributions in the targets. The spatial distribution of temperature is dependent on the target thickness, and a thin target shows an advantage to generate uniform warm dense conditions in a large area.

Published

2018

35. Experimental Observation of a Current-Driven Instability in a Neutral Electron-Positron Beam.

Author

Warwick J, Dzelzainis T, Dieckmann ME, Schumaker W, Doria D, Romagnani L, Poder K, Cole JM, Alejo A, Yeung M, Krushelnick K, Mangles SPD, Najmudin Z, Reville B, Samarin GM, Symes DD, Thomas AGR, Borghesi M, and Sarri G

Abstract

We report on the first experimental observation of a current-driven instability developing in a quasineutral matter-antimatter beam. Strong magnetic fields (≥1  T) are measured, via means of a proton radiography technique, after the propagation of a neutral electron-positron beam through a background electron-ion plasma. The experimentally determined equipartition parameter of ε&#95;{B}≈10^{-3} is typical of values inferred from models of astrophysical gamma-ray bursts, in which the relativistic flows are also expected to be pair dominated. The data, supported by particle-in-cell simulations and simple analytical estimates, indicate that these magnetic fields persist in the background plasma for thousands of inverse plasma frequencies. The existence of such long-lived magnetic fields can be related to analog astrophysical systems, such as those prevalent in lepton-dominated jets.

Published

2017

36. Momentum transport and nonlocality in heat-flux-driven magnetic reconnection in high-energy-density plasmas.

Author

Liu C, Fox W, Bhattacharjee A, Thomas AGR, and Joglekar AS

Abstract

Recent theory has demonstrated a novel physics regime for magnetic reconnection in high-energy-density plasmas where the magnetic field is advected by heat flux via the Nernst effect. Here we elucidate the physics of the electron dissipation layer in this regime. Through fully kinetic simulation and a generalized Ohm's law derived from first principles, we show that momentum transport due to a nonlocal effect, the heat-flux-viscosity, provides the dissipation mechanism for magnetic reconnection. Scaling analysis, and simulations show that the reconnection process comprises a magnetic field compression stage and quasisteady reconnection stage, and the characteristic width of the current sheet in this regime is several electron mean-free paths. These results show the important interplay between nonlocal transport effects and generation of anisotropic components to the distribution function.

Published

2017

37. Enhancement of THz generation by feedback-optimized wavefront manipulation.

Author

Hah J, Jiang W, He ZH, Nees JA, Hou B, Thomas AGR, and Krushelnick K

Abstract

We apply active feedback optimization methods to pyroelectric measurements of a THz signal generated by four wave mixing in air using 1 mJ to 12 mJ, 35 fs laser pulses operating at 12 kHz repetition rate. A genetic algorithm, using the THz signal as a figure of merit, determines the voltage settings to a deformable mirror and results in up to a 6 fold improvement in the THz signal compared with settings optimized for the best focus. It is possible to optimize for different THz generation processes using this technique.

Published

2017

38. Brilliant X-rays using a Two-Stage Plasma Insertion Device.

Author

Holloway JA, Norreys PA, Thomas AGR, Bartolini R, Bingham R, Nydell J, Trines RMGM, Walker R, and Wing M

Abstract

Particle accelerators have made an enormous impact in all fields of natural sciences, from elementary particle physics, to the imaging of proteins and the development of new pharmaceuticals. Modern light sources have advanced many fields by providing extraordinarily bright, short X-ray pulses. Here we present a novel numerical study, demonstrating that existing third generation light sources can significantly enhance the brightness and photon energy of their X-ray pulses by undulating their beams within plasma wakefields. This study shows that a three order of magnitude increase in X-ray brightness and over an order of magnitude increase in X-ray photon energy is achieved by passing a 3 GeV electron beam through a two-stage plasma insertion device. The production mechanism micro-bunches the electron beam and ensures the pulses are radially polarised on creation. We also demonstrate that the micro-bunched electron beam is itself an effective wakefield driver that can potentially accelerate a witness electron beam up to 6 GeV.

Published

2017

39. Capturing Structural Dynamics in Crystalline Silicon Using Chirped Electrons from a Laser Wakefield Accelerator.

Author

He ZH, Beaurepaire B, Nees JA, Gallé G, Scott SA, Pérez JRS, Lagally MG, Krushelnick K, Thomas AGR, and Faure J

Abstract

Recent progress in laser wakefield acceleration has led to the emergence of a new generation of electron and X-ray sources that may have enormous benefits for ultrafast science. These novel sources promise to become indispensable tools for the investigation of structural dynamics on the femtosecond time scale, with spatial resolution on the atomic scale. Here, we demonstrate the use of laser-wakefield-accelerated electron bunches for time-resolved electron diffraction measurements of the structural dynamics of single-crystal silicon nano-membranes pumped by an ultrafast laser pulse. In our proof-of-concept study, we resolve the silicon lattice dynamics on a picosecond time scale by deflecting the momentum-time correlated electrons in the diffraction peaks with a static magnetic field to obtain the time-dependent diffraction efficiency. Further improvements may lead to femtosecond temporal resolution, with negligible pump-probe jitter being possible with future laser-wakefield-accelerator ultrafast-electron-diffraction schemes.

Published

2016