Meter-scale conditioned hydrodynamic optical-field-ionized plasma channels

Picksley, A.; Alejo, A.; Shalloo, R. J.; Arran, Christopher; Boetticher, Alexander von; Corner, L.; Holloway, J.; Jonnerby, Jakob; Jakobsson, Oscar; Thornton, C.; Walczak, R.; Hooker, S. M.

doi:10.1103/physreve.102.053201

Cited by 26 publications

(16 citation statements)

References 37 publications

(53 reference statements)

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“…Such intensities would correspond to a wavelength of λ a = 9 m. Generating and maintaining long laser focuses might be possible with a variety of approaches in the future. For example, recent plasma-waveguides are capable of maintaining a laser focus over 10 m scales [22,23]. It is also worth pointing out that the focus length decreases mildly with laser power, hence the problem will become marginally simpler in the future.…”

Section: Discussion and Applicationmentioning

confidence: 99%

Parametric co-linear axion photon instability

Beyer¹,

Marocco²,

Danson³

et al. 2021

Preprint

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Axions and axion-like particles generically couple to QED via the axion-photon-photon interaction. This leads to a modification of Maxwell's equations known in the literature as axionelectrodynamics. The new form of Maxwell's equations gives rise to a new parametric instability in which a strong pump decays into a scattered light wave and an axion. This axion mode grows exponentially in time and leads to a change in the polarisation of the initial laser beam, therefore providing a signal for detection. Currently operating laser systems can put bounds on the axion parameter space, however longer pulselengths are necessary to reach the current best laboratory bounds of light-shining through wall experiments.

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Section: Discussion and Applicationmentioning

confidence: 99%

Parametric co-linear axion photon instability

Beyer¹,

Marocco²,

Danson³

et al. 2021

Preprint

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show abstract

“…Although the initial temperature is high enough to allow for full ionization of the plasma column, a neutral gas collar appears in the early stages of the expansion. The simulation shows the number of free electrons to remain approximately constant throughout the expansion (see the Supplemental Material [33]), indicating that the accumulation of neutral gas in the region of the shock is caused by the high pressure in the inner regions of the channel.…”

Section: Hydrodynamic Simulationsmentioning

confidence: 93%

“…The experiments were undertaken with the 5-Hz repetitionrate Astra-Gemini TA2 laser at the Central Laser Facilty, UK. The setup employed has been described previously [27] and is described in detail in the Supplemental Material [33], so here we provide only an outline.…”

Section: Methodsmentioning

confidence: 99%

Meter-scale conditioned hydrodynamic optical-field-ionized plasma channels

Hooker

Alejo

Arran

et al. 2021

Laser Acceleration of Electrons, Protons, and Ions VI

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We demonstrate through experiments and numerical simulations that low-density, low-loss, meter-scale plasma channels can be generated by employing a conditioning laser pulse to ionize the neutral gas collar surrounding a hydrodynamic optical-field-ionized (HOFI) plasma channel. We use particle-in-cell simulations to show that the leading edge of the conditioning pulse ionizes the neutral gas collar to generate a deep, low-loss plasma channel which guides the bulk of the conditioning pulse itself as well as any subsequently injected pulses. In proof-of-principle experiments, we generate conditioned HOFI (CHOFI) waveguides with axial electron densities of n e0 ≈ 1×10 17 cm −3 and a matched spot size of 26 μm. The power attenuation length of these CHOFI channels was calculated to be L att = (21 ± 3) m, more than two orders of magnitude longer than achieved by HOFI channels. Hydrodynamic and particle-in-cell simulations demonstrate that meter-scale CHOFI waveguides with attenuation lengths exceeding 1 m could be generated with a total laser pulse energy of only 1.2 J per meter of channel. The properties of CHOFI channels are ideally suited to many applications in high-intensity light-matter interactions, including multi-GeV plasma accelerator stages operating at high pulse repetition rates.

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“…We note that the key components required to realize this new approach have all recently been demonstrated, and in principle all are capable of multi-kilohertz operation. These include: metre-scale, low-loss, all-optical plasma waveguides [64][65][66][67][68][69][70]; 100 mJ-scale, sub-50 fs seed laser pulses [71]; and joule-level, few-picosecond, 1030 nm drive laser pulses [43,45]. The proposed scheme requires tight temporal and spatial overlap of multiple laser beams, the most challenging of which are: (i) control of the delay between the electron bunch and the seed pulse (∼ 10 fs); and (ii) control of the pointing of the seed and drive pulses relative to the waveguide axes (< 10 µrad).…”

mentioning

confidence: 99%

“…The proposed scheme requires tight temporal and spatial overlap of multiple laser beams, the most challenging of which are: (i) control of the delay between the electron bunch and the seed pulse (∼ 10 fs); and (ii) control of the pointing of the seed and drive pulses relative to the waveguide axes (< 10 µrad). These requirements have already been met [67,68,70,[72][73][74][75] in experiments operating at f rep = 1 Hz, and even tighter tolerances could be achieved with the improved feedback made possible by kHz operation. In this document we provide additional information on the analytic theory and Particle-In-Cell (PIC) simulations presented in the main paper.…”

mentioning

confidence: 99%

Gev-Scale Accelerators Driven by Plasma-Modulated Pulses from Kilohertz Lasers

2021

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We describe a new approach for driving GeV-scale plasma accelerators with long laser pulses. We show that the temporal phase of a long, high-energy driving laser pulse can be modulated periodically by co-propagating it with a low-amplitude plasma wave driven by a short, low-energy seed pulse. Compression of the modulated driver by a dispersive optic generates a train of short pulses suitable for resonantly driving a plasma accelerator. Modulation of the driver occurs via well-controlled linear processes, as confirmed by good agreement between particle-in-cell (PIC) simulations and an analytic model. PIC simulations demonstrate that a 1.7 J, 1 ps driver and a 140 mJ, 40 fs seed pulse can accelerate electrons to energies of 0.65 GeV in a plasma channel with an axial density of 2.5 × 10 17 cm −3 . This work opens a route to high-repetition-rate, GeV-scale plasma accelerators driven by thin-disk lasers, which can provide joule-scale, picosecond-duration laser pulses at multikilohertz repetition rates and high wall-plug efficiencies.

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Meter-scale conditioned hydrodynamic optical-field-ionized plasma channels

Cited by 26 publications

References 37 publications

Parametric co-linear axion photon instability

Parametric co-linear axion photon instability

Meter-scale conditioned hydrodynamic optical-field-ionized plasma channels

Gev-Scale Accelerators Driven by Plasma-Modulated Pulses from Kilohertz Lasers

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