Dense micron-sized electron plasmas, such as those generated upon irradiation of nanostructured metallic surfaces by intense femtosecond laser pulses, constitute a rich playground to study light-matter interactions, many-body phenomena, and out-of-equilibrium charge dynamics. Besides their fundamental interest, laser-induced plasmas hold great potential for the generation of localized terahertz radiation pulses. However, the underlying mechanisms ruling the formation and evolution of such plasmas are not yet well understood. Here, we develop a comprehensive microscopic theory to predictably describe the spatiotemporal dynamics of laser-pulse-induced plasmas. Through detailed analysis of electron emission, metal screening, and plasma cloud interactions, we investigate the spatial, temporal, and spectral characteristics of the so-generated terahertz fields, which can be extensively controlled through the metal morphology and the illumination conditions. We further describe the interaction with femtosecond electron beams to explain recent ultrafast electron microscopy experiments, whereby the position and temporal dependence of the observed electron acceleration permits assessing the associated terahertz field. Besides its potential application to the design of low-frequency light sources, our work contributes fundamental insight into the generation and dynamics of micron-scale electron plasmas and their interaction with ultrafast electron pulses.

Dias, E., Madan, I., Gargiulo, S., Barantani, F., Yannai, M., Vanacore, G., et al. (2023). Generation and control of localized terahertz fields in photoemitted electron plasmas. NANOSCALE ADVANCES, 5(14), 3634-3645 [10.1039/d3na00168g].

Generation and control of localized terahertz fields in photoemitted electron plasmas

Vanacore G. M.;
2023

Abstract

Dense micron-sized electron plasmas, such as those generated upon irradiation of nanostructured metallic surfaces by intense femtosecond laser pulses, constitute a rich playground to study light-matter interactions, many-body phenomena, and out-of-equilibrium charge dynamics. Besides their fundamental interest, laser-induced plasmas hold great potential for the generation of localized terahertz radiation pulses. However, the underlying mechanisms ruling the formation and evolution of such plasmas are not yet well understood. Here, we develop a comprehensive microscopic theory to predictably describe the spatiotemporal dynamics of laser-pulse-induced plasmas. Through detailed analysis of electron emission, metal screening, and plasma cloud interactions, we investigate the spatial, temporal, and spectral characteristics of the so-generated terahertz fields, which can be extensively controlled through the metal morphology and the illumination conditions. We further describe the interaction with femtosecond electron beams to explain recent ultrafast electron microscopy experiments, whereby the position and temporal dependence of the observed electron acceleration permits assessing the associated terahertz field. Besides its potential application to the design of low-frequency light sources, our work contributes fundamental insight into the generation and dynamics of micron-scale electron plasmas and their interaction with ultrafast electron pulses.
Articolo in rivista - Articolo scientifico
Dynamics; Electrons; Laser produced plasmas; Laser pulses; Laser theory; Terahertz waves
English
4-mag-2023
2023
5
14
3634
3645
none
Dias, E., Madan, I., Gargiulo, S., Barantani, F., Yannai, M., Vanacore, G., et al. (2023). Generation and control of localized terahertz fields in photoemitted electron plasmas. NANOSCALE ADVANCES, 5(14), 3634-3645 [10.1039/d3na00168g].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/451559
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