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Plasmonics has opened unforeseen applications due to its sub-wavelength scale control over modes of collective oscillations of free electron gas in solids. This control is only possible due to nano-structuring of the underlying media. I introduce my TeraVolts per meter (TVm−1) plasmonics initiative which promises many tens of TVm−1 fields by relying on nanostructured materials to access a novel class of relativistic plasmonic modes excited as “trailing wake” of intense ultrashort particle bunches. Nanomaterial tubes with a hollow core are critical to mitigate the disruptive effects of collision of the particle beam with the ionic-lattice. Specifically, I present underlying concepts and theoretical model of highly nonlinear surface plasmonic waves. These surface waves are sustained by a train of “crunch-in” surface plasmons with large-scale electron-ion charge-separation which leads to tens of TVm−1 fields. The crunch-in surface plasmons are thus strongly electrostatic unlike other plasmonic modes. Access to unprecedented plasmonic fields opens far-reaching possibilities for transformative impact.
Aakash A. Sahai
"Emergence of TeraVolts per meter plasmonics using relativistic surface plasmonic modes", Proc. SPIE 11797, Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIX, 117972A (6 August 2021); https://doi.org/10.1117/12.2596637
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Aakash A. Sahai, "Emergence of TeraVolts per meter plasmonics using relativistic surface plasmonic modes," Proc. SPIE 11797, Plasmonics: Design, Materials, Fabrication, Characterization, and Applications XIX, 117972A (6 August 2021); https://doi.org/10.1117/12.2596637