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Thesis
Home   /   Thesis   /   Plasma Mirrors Towards Extreme Intensity Light Sources and High-Quality Compact Electron Accelerators

Plasma Mirrors Towards Extreme Intensity Light Sources and High-Quality Compact Electron Accelerators

Condensed matter physics, chemistry & nanosciences Radiation-matter interactions Theoretical physics

Abstract

The research programs conducted at the Lasers Interactions and Dynamics Laboratory of the French Atomic Energy Commission (CEA) aim to understand the fundamental processes involved in light-matter interactions and their applications. As part of the CEA-LIDYL, the Physics at High Intensity (PHI) group conducts studies of laser-matter interactions at extreme intensities, for which matter turns into an ultra-relativistic plasma. Using theory, simulations and experiments, researchers develop and test new concepts to control the laser-plasma interaction with the aim to produce novel relativistic electron and X-UV attosecond light sources, with potential applications to fundamental research, medicine and industry.

In collaboration with the Lawrence Berkeley National Laboratory, the group is a core developer of the exascale Particle-In-Cell (PIC) codes WarpX/PICSAR for the high-fidelity modelling of laser-matter interactions. It also pioneered the study and control of remarkable optical components called ‘plasma mirrors’, which can be obtained upon focusing a high-power laser with high-contrast on an initially solid target. In the past five years, the PHI group has developed two concepts exploiting plasma mirrors to manipulate extreme light for pushing the frontiers of high-field science. The first concept uses relativistic plasma mirrors to amplify the intensity of existing lasers by orders of magnitude and probe novel regimes of Strong-Field Quantum Electrodynamics (SF-QED). The second uses plasma mirrors as high-charge injectors to level up the charge produced in laser-plasma accelerators (LPAs) to enable their use for medical studies, industrial applications and fundamental research (collider design, electron-laser collisions for SF-QED studies).

In this context, the PhD candidate will first improve our simulation tool WarpX to speed-up plasma mirror simulations. They will then use WarpX to optimize the use of plasma mirrors as intensity boosters for the study of SF-QED. In collaboration with Brigitte Cros's team at CNRS and within the framework of novel collider designs based on Laser-Plasma Accelerators (LPAs), the PhD candidate will finally investigate and optimize the use of plasma mirrors as optical components for the coupling of multiple LPA stages. This will be crucial for developing compact acceleration schemes that can be scaled to produce high-energy, high-quality electron beams.

Laboratory

Institut rayonnement et matière de Saclay
Service Laboratoire Interactions, Dynamique et Lasers
Physique à Haute Intensité
Paris-Saclay
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