J. T. Mendonça scite author profile

We show analytically and through three-dimensional particle-in-cell simulations that non-linear wakefields driven by Laguerre-Gaussian laser pulses can lead to hollow electron self-injection and positron acceleration. We find that higher order lasers can drive donut shaped blowout wakefields with strong positron accelerating gradients comparable to those of a spherical bubble. Corresponding positron focusing forces can be more than an order of magnitude stronger than electron focusing forces in a spherical bubble. Required laser intensities and energies to reach the non-linear donut shaped blowout are within state-of-the-art experimental conditions.

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Neutrino Driven Streaming Instabilities in a Dense Plasma

Silva

et al. 1999

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Theory of Photon Acceleration

Mendonça¹

2000

113

109

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Amplification and generation of ultra-intense twisted laser pulses via stimulated Raman scattering

et al. 2016

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Twisted Laguerre–Gaussian lasers, with orbital angular momentum and characterized by doughnut-shaped intensity profiles, provide a transformative set of tools and research directions in a growing range of fields and applications, from super-resolution microcopy and ultra-fast optical communications to quantum computing and astrophysics. The impact of twisted light is widening as recent numerical calculations provided solutions to long-standing challenges in plasma-based acceleration by allowing for high-gradient positron acceleration. The production of ultra-high-intensity twisted laser pulses could then also have a broad influence on relativistic laser–matter interactions. Here we show theoretically and with ab initio three-dimensional particle-in-cell simulations that stimulated Raman backscattering can generate and amplify twisted lasers to petawatt intensities in plasmas. This work may open new research directions in nonlinear optics and high–energy-density science, compact plasma-based accelerators and light sources.

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Inverse Faraday Effect with Linearly Polarized Laser Pulses

Ali

Davies²,

Mendonça³

2010

Phys. Rev. Lett.

109

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The inverse Faraday effect is usually associated with circularly polarized radiation; here, we show that it can also occur for linearly polarized radiation. The quasistatic axial magnetic field generated by a laser propagating in plasma can be calculated by considering both the spin and the orbital angular momenta of the laser pulse. A net spin is present when the radiation is circularly polarized and a net orbital angular momentum is present if there is any deviation from perfect rotational symmetry. The orbital angular momentum gives an additional contribution to the axial magnetic field that can enhance or reduce the effect usually attributed to circular polarization and strongly depends on the intensity profile of the Laguerre-Gaussian modes involving the azimuthal and radial mode numbers.

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J. T. Mendonça

Nonlinear Laser Driven Donut Wakefields for Positron and Electron Acceleration

Neutrino Driven Streaming Instabilities in a Dense Plasma

Theory of Photon Acceleration

Amplification and generation of ultra-intense twisted laser pulses via stimulated Raman scattering

Inverse Faraday Effect with Linearly Polarized Laser Pulses

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