Controlling Proton Acceleration with Advanced Gold Nanoantennas in a Kinetic Plasma Environment

Zsukovszki, Konstantin and Papp, István (2026) Controlling Proton Acceleration with Advanced Gold Nanoantennas in a Kinetic Plasma Environment. PARTICLES, 9 (2). No.-51. ISSN 2571-712X

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Abstract

Metallic nanoantennas are promising structures for enhancing energy transfer in high-intensity laser–matter interactions, especially in nanoplasmonic-assisted fusion. Under ultrashort laser pulses, they generate strong localized fields, modify ionization dynamics, and significantly affect charge acceleration in dense media. In this work, we present a comprehensive particle-in-cell (PIC) study of gold nanoantennas of various geometries—dipoles, planar crosses, three-dimensional crosses, and Yagi-inspired planar structures—irradiated by near-infrared femtosecond pulses at intensities at a range of ~4 × 1017–4 × 1018 W/cm2. The antenna structures are embedded in a dense hydrogen-rich medium, allowing us to follow electron emission, gold ionization, and proton acceleration self-consistently. Crossed and Yagi-type geometries exhibit more robust resonant behavior than dipoles, with higher field localization and greatly reduced sensitivity to incident polarization. The proton energies increase to ~200 keV at 4 × 1017 W/cm2, and saturate around ~300 keV at a higher intensity >~4 × 1018 W/cm2, dependent on the geometry. This happens largely due to a rapid loss of conduction electrons from the gold structures. Our results highlight Yagi-based and cross-based nanoantennas as promising resonant dopes for laser-driven energy coupling and point toward optimized multi-arm architectures for future nanofusion-target engineering applications.

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