Particle simulation of plasmons

Ding, Waverly W.; Lim, Jeremy; Bich, Hue Thi; Xiong, X.; Mahfoud, Zackaria; Png, Ching Eng; Bosman, Michel; Ang, L. K.; Wu, Lin

doi:10.1515/nanoph-2020-0067

Cited by 12 publications

(7 citation statements)

References 48 publications

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“…The suggested secondary enhancing mechanism via plasmonic field confinement can be directly applied to plasmon-induced hot carrier generation and applications involving metal nanoparticles. , The spill-out effect of the electron wave function in quantum plasmonics − could be analyzed for our plasmonic field confinement mechanism and also in the ultrafast regime. − On the other hand, our photoemission model can be further developed beyond a triangular-barrier approximation to characterize the photoemission through an irregular double-barrier potential profile. Meanwhile, our analytical photoemission model has shown excellent agreement with both experiments , and numerical solutions for pulse durations down to 30 fs; it is instructive to include the effects of nonequilibrium heating , for even shorter pulse durations.…”

Section: Discussionmentioning

confidence: 99%

Plasmon-Enhanced Resonant Photoemission Using Atomically Thick Dielectric Coatings

et al. 2020

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By proposing an atomically thick dielectric coating on a metal nanoemitter, we theoretically show that the optical field tunneling of ultrafast-laser-induced photoemission can occur at an ultralow incident field strength of 0.03 V/nm. This coating strongly confines plasmonic fields and provides secondary field enhancement beyond the geometrical plasmon field enhancement effect, which can substantially reduce the barrier and enable more efficient photoemission. We numerically demonstrate that a 1 nm thick layer of SiO 2 around a Aunanopyramid will enhance the resonant photoemission current density by 2 orders of magnitude, where the transition from multiphoton absorption to optical field tunneling is accessed at an incident laser intensity at least 10 times lower than that of the bare nanoemitter. The effects of the coating properties such as refractive index, thickness, and geometrical settings are studied, and tunable photoemission is numerically demonstrated by using different ultrafast lasers. Our approach can also directly be extended to nonmetal emitters, tofor example2D material coatings, and to plasmon-induced hot carrier generation.

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Section: Discussionmentioning

confidence: 99%

Plasmon-Enhanced Resonant Photoemission Using Atomically Thick Dielectric Coatings

et al. 2020

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“…Only now, the quantum theory of the electron gas enters, when summing up the contributions from many such electrons to form a current density J = −ne𝒗, where n is the density of free conduction electrons in the conduction band of the metal [86]. In passing, we note that rather than a continuum formulation, one may also follow a computationally more challenging particle-simulation approach, where one aims to keep track of the many individual conduction electrons [87,88]. Following the continuum formulation, the end result is nothing but Ohm's law, but now with a semiclassical expression for the frequency-dispersive conductivity [86] 𝜎(𝜔)…”

Section: The Drude Model Underlying Plasmonicsmentioning

confidence: 99%

Mesoscopic electrodynamics at metal surfaces

Mortensen

2021

Nanophotonics

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Plasmonic phenomena in metals are commonly explored within the framework of classical electrodynamics and semiclassical models for the interactions of light with free-electron matter. The more detailed understanding of mesoscopic electrodynamics at metal surfaces is, however, becoming increasingly important for both fundamental developments in quantum plasmonics and potential applications in emerging light-based quantum technologies. The review offers a colloquial introduction to recent mesoscopic formalism, ranging from quantum-corrected hydrodynamics to microscopic surface-response formalism, offering also perspectives on possible future avenues.

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“…Plasma numerical simulations can provide information including the spatial and temporal distribution of free radicals and charged particles, their content, reaction rates of various collision processes, mass transfer kinetics, and energy. Commonly used simulation models are particle model, 69 fluid model, 70 and global models 71 . The most widely used of these is the fluid model, which reflects the internal properties of the plasma but is also limited by the volume of calculations and the stability of the algorithm.…”

Section: Artpmentioning

confidence: 99%

Recent progress of atmospheric and room‐temperature plasma as a new and promising mutagenesis technology

Li,

Shen,

Ding

et al. 2024

Cell Biochemistry & Function

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At present, atmospheric and room‐temperature plasma (ARTP) is regarded as a new and powerful mutagenesis technology with the advantages of environment‐friendliness, operation under mild conditions, and fast mutagenesis speed. Compared with traditional mutagenesis strategies, ARTP is used mainly to change the structure of microbial DNA, enzymes, and proteins through a series of physical, chemical, and electromagnetic effects with the organisms, leading to nucleotide breakage, conversion or inversion, causing various DNA damages, so as to screen out the microbial mutants with better biological characteristics. As a result, in recent years, ARTP mutagenesis and the combination of ARTP with traditional mutagenesis have been widely used in microbiology, showing great potential for application. In this review, the recent progress of ARTP mutagenesis in different application fields and bottlenecks of this technology are systematically summarized, with a view to providing a theoretical basis and technical support for better application. Finally, the outlook of ARTP mutagenesis is presented, and we identify the challenges in the field of microbial mutagenesis by ARTP.

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Particle simulation of plasmons

Cited by 12 publications

References 48 publications

Plasmon-Enhanced Resonant Photoemission Using Atomically Thick Dielectric Coatings

Plasmon-Enhanced Resonant Photoemission Using Atomically Thick Dielectric Coatings

Mesoscopic electrodynamics at metal surfaces

Recent progress of atmospheric and room‐temperature plasma as a new and promising mutagenesis technology

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