K. U. Akli scite author profile

Articles you may be interested inOn the electrodynamic model of ultra-relativistic laser-plasma interactions caused by radiation reaction effects Phys. Plasmas 20, 113111 (2013); 10.1063/1.4835215Numerical modeling of radiation-dominated and quantum-electrodynamically strong regimes of laser-plasma interaction Phys.When extremely intense lasers (I ! 10 22 W/cm 2 ) interact with plasmas, a significant fraction of the pulse energy is converted into photon emission in the multi-MeV energy range. This emission results in a radiation reaction (RR) force on electrons, which becomes important at ultrahigh intensities. Using three-dimensional particle-in-cell simulations which include a quantum electrodynamics model for the c-photons emission, the corresponding RR force and electron-positron pair creation, the energy partition in the laser-plasma system is investigated. At sufficiently high laser amplitudes, the fraction of laser energy coupled to electrons decreases, while the energy converted to c-photons increases. The interaction becomes an efficient source of c-rays when I > 10 24 W/cm 2 , with up to 40% of the laser energy converted to high-energy photons. A systematic study of energy partition and c-photon emission angle shows the influence of laser intensity and polarization for two plasma conditions: high-density carbon targets and a low-density hydrogen targets. We find that in the opaque region, the laser-to-photon conversion efficiency scales as I 3=2 0

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Towards manipulating relativistic laser pulses with micro-tube plasma lenses

Snyder

Pukhov

et al. 2016

Sci Rep

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Efficient coupling of intense laser pulses to solid-density matter is critical to many applications including ion acceleration for cancer therapy. At relativistic intensities, the focus has been mainly on investigating various laser beams irradiating initially overdense flat interfaces with little or no control over the interaction. Here, we propose a novel approach that leverages recent advancements in 3D direct laser writing (DLW) of materials and high contrast lasers to manipulate the laser-matter interactions on the micro-scales. We demonstrate, via simulations, that usable intensities ≥1023 Wcm−2 could be achieved with current tabletop lasers coupled to micro-engineered plasma lenses. We show that these plasma optical elements act as a lens to focus laser light. These results open new paths to engineering light-matter interactions at ultra-relativistic intensities.

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Temperature sensitivity of Cu Kα imaging efficiency using a spherical Bragg reflecting crystal

Akli

Key

Chung

et al. 2007

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The interaction of a 75J 10ps, high intensity laser beam with low-mass, solid Cu targets is investigated. Two instruments were fielded as diagnostics of Cu K-shell emission from the targets: a single photon counting spectrometer provided the absolute Kα yield [C. Stoeckl et al., Rev. Sci. Instrum. 75, 3705 (2004)] and a spherically bent Bragg crystal recorded 2D monochromatic images with a spatial resolution of 10μm [J. A. Koch et al., Rev. Sci. Instrum. 74, 2130 (2003)]. Due to the shifting and broadening of the Kα spectral lines with increasing temperature, there is a temperature dependence of the crystal collection efficiency. This affects measurements of the spatial pattern of electron transport, and it provides a temperature diagnostic when cross calibrated against the single photon counting spectrometer. The experimental data showing changing collection efficiency are presented. The results are discussed in light of modeling of the temperature-dependent spectrum of Cu K-shell emission.

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K. U. Akli

Radiation-Reaction Trapping of Electrons in Extreme Laser Fields

Energy partition, γ-ray emission, and radiation reaction in the near-quantum electrodynamical regime of laser-plasma interaction

Towards manipulating relativistic laser pulses with micro-tube plasma lenses

Temperature sensitivity of Cu Kα imaging efficiency using a spherical Bragg reflecting crystal

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