Scattering of a Bessel Pincer Light-Sheet Beam on a Charged Particle at Arbitrary Size

Electromagnetic scattering is a routine tool for rapid, non-contact characterization of particle media. In previous work, the interaction targets of scattering intensity, scattering efficiency, and extinction efficiency of Bessel pincer light-sheet beams were all aimed at dielectric spheres. However...

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Bibliographic Details
Published in:Micromachines (Basel) 2024-07, Vol.15 (8), p.975
Main Authors: Zhang, Shu, Chen, Shiguo, Wei, Qun, Li, Renxian, Wei, Bing, Song, Ningning
Format: Article
Language:English
Subjects:
Absorptivity
Beamforming
Bessel functions
Bessel pincer light-sheet beam
Boundary conditions
Charge efficiency
charged particle
Charged particles
Efficiency
Electric fields
Electromagnetic scattering
Extinction
Far fields
GLMT
Image resolution
Light
Light sheets
Luminous intensity
Medical imaging
Microbiology
Mie scattering
Optics
Parameters
Particle beams
Permeability
Radiation
Refractivity
Scattering (Physics)
Spheres
Surface charge
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Summary:Electromagnetic scattering is a routine tool for rapid, non-contact characterization of particle media. In previous work, the interaction targets of scattering intensity, scattering efficiency, and extinction efficiency of Bessel pincer light-sheet beams were all aimed at dielectric spheres. However, most particles in nature are charged. Considering the boundary condition on a charged sphere, the beam shape coefficients (BSCs) (pmn,qmn) of the charged spherical particle illuminated by a Bessel pincer light-sheet beam are obtained. The extinction, scattering, and absorption efficiencies are derived under the generalized Lorenz-Mie theory (GLMT) framework. This study reveals the significant differences in scattering characteristics of Bessel pincer light-sheet beams on a charged particle compared to traditional beams. The simulations show a few apparent differences in the far-field scattering intensity and efficiencies between charged and natural spheres under the influence of dimensionless size parameters. As dimensionless parameters increase, the difference between the charged and neutral spheres decreases. The effects of refractive index and beam parameters on scattering, extinction, and absorption coefficients are different but tend to converge with increasing dimensionless parameters. When applied to charged spheres with different refractive indices, the scattering, extinction, and absorption efficiencies of Bessel pincer light-sheet beams change with variations in surface charge. However, once the surface charge reaches saturation, these efficiencies become stable. This study is significant for understanding optical manipulation and super-resolution imaging in single-molecule microbiology.
ISSN:2072-666X
2072-666X
DOI:10.3390/mi15080975