The development of novel target concepts is crucial to make laser-driven acceleration of ion beams suitable for applications. We tested double-layer targets formed of an ultralow density nanostructured carbon layer (∼7 mg=cm3, 8–12 μm–thick) deposited on a μm–thick solid Al foil. A systematic increase in the total number of the accelerated ions (protons and C6þ) as well as enhancement of both their maximum and average energies was observed with respect to bare solid foil targets. Maximum proton energies up to 30 MeV were recorded. Dedicated three-dimensional particle-in-cell simulations were in remarkable agreement with the experimental results, giving clear indication of the role played by the target nanostructures in the interaction process.
Toward high-energy laser-driven ion beams: Nanostructured double-layer targets
PASSONI, MATTEO;PRENCIPE, IRENE;FEDELI, LUCA;DELLASEGA, DAVID;CIALFI, LORENZO;
2016-01-01
Abstract
The development of novel target concepts is crucial to make laser-driven acceleration of ion beams suitable for applications. We tested double-layer targets formed of an ultralow density nanostructured carbon layer (∼7 mg=cm3, 8–12 μm–thick) deposited on a μm–thick solid Al foil. A systematic increase in the total number of the accelerated ions (protons and C6þ) as well as enhancement of both their maximum and average energies was observed with respect to bare solid foil targets. Maximum proton energies up to 30 MeV were recorded. Dedicated three-dimensional particle-in-cell simulations were in remarkable agreement with the experimental results, giving clear indication of the role played by the target nanostructures in the interaction process.| File | Dimensione | Formato | |
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