O. Tresca scite author profile

The propagation of fast electrons produced in the interaction of relativistically intense, picosecond laser pulses with solid targets is experimentally investigated using K α emission as a diagnostic. The role of fast electron refluxing within the target, which occurs when the electrons are reflected by the sheath potentials formed at the front and rear surfaces, is elucidated. The targets consist of a Cu fluorescence layer of fixed thickness at the front surface backed with a propagation layer of CH, the thickness of which is varied to control the number of times the refluxing fast electron population transits the Cu fluorescence layer. Enhancements in the K α yield and source size are measured as the thickness of the CH layer is decreased. Comparison with analytical and numerical modelling confirms that significant refluxing occurs and highlights the importance of considering this phenomenon when deriving information on fast electron transport from laser-solid interaction experiments involving relatively thin targets.

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Spectral Modification of Shock Accelerated Ions Using a Hydrodynamically Shaped Gas Target

Tresca

Dover

Cook

et al. 2015

Phys. Rev. Lett.

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Effect of Lattice Structure on Energetic Electron Transport in Solids Irradiated by Ultraintense Laser Pulses

et al. 2011

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The effect of lattice structure on the transport of energetic (MeV) electrons in solids irradiated by ultraintense laser pulses is investigated using various allotropes of carbon. We observe smooth electron transport in diamond, whereas beam filamentation is observed with less ordered forms of carbon. The highly ordered lattice structure of diamond is shown to result in a transient state of warm dense carbon with metalliclike conductivity, at temperatures of the order of 1-100 eV, leading to suppression of electron beam filamentation.

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Laser pulse propagation and enhanced energy coupling to fast electrons in dense plasma gradients

et al. 2014

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Laser energy absorption to fast electrons during the interaction of an ultraintense (10 20 W cm −2 ), picosecond laser pulse with a solid is investigated, experimentally and numerically, as a function of the plasma density scale length at the irradiated surface. It is shown that there is an optimum density gradient for efficient energy coupling to electrons and that this arises due to strong selffocusing and channeling driving energy absorption over an extended length in the preformed plasma. At longer density gradients the laser filaments, resulting in significantly lower overall energy coupling. As the scale length is further increased, a transition to a second laser energy absorption process is observed experimentally via multiple diagnostics. The results demonstrate that it is possible to significantly enhance laser energy absorption and coupling to fast electrons by dynamically controlling the plasma density gradient.

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Calibration of Thomson parabola—MCP assembly for multi-MeV ion spectroscopy

Prasad

Doria

Ter‐Avetisyan

et al. 2010

Nuclear Instruments and Methods in Physics Research Section A:

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O. Tresca

Refluxing of fast electrons in solid targets irradiated by intense, picosecond laser pulses

Spectral Modification of Shock Accelerated Ions Using a Hydrodynamically Shaped Gas Target

Effect of Lattice Structure on Energetic Electron Transport in Solids Irradiated by Ultraintense Laser Pulses

Laser pulse propagation and enhanced energy coupling to fast electrons in dense plasma gradients

Calibration of Thomson parabola—MCP assembly for multi-MeV ion spectroscopy

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