Unusual optical phenomena inside and near a rotating sphere: the photonic hook and resonance

Tang, Huan; Shi, Zhuoyuan; Zhang, Yuan; Li, Renxian; Wei, Bing; Gong, Shuhong; Minin, Igor V.; Minin, Oleg V.

doi:10.1364/oe.518794

Cited by 5 publications

References 71 publications

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Resonance scattering generated by rotating bodies

Li,

Tang,

Wei

et al. 2024

Phys. Scr.

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The scattering of rotating bodies to a polarized plane wave, including the dielectric cylinder and sphere, is studied. The resonance caused by rotation is emphasized. Numerical results prove that the resonance scattering caused by rotation can be realized in the optical range. It is sensitive to the rotation dimensionless parameter γ. The internal Mie mode corresponding to the electromagnetic field intensity changes with γ, and the resonant mode appears when the particle rotates at a specific speed. Moreover, the resonant mode changes with γ. It causes resonance scattering to appear in the same particle at different speeds. Inside particles, resonant rings are composed of a series of array points and are determined by γ. Under resonance conditions, the energy near the rotating cylinder is consistent with its rotation direction. In contrast, the direction of energy flow in the rotating sphere model is opposite to the direction of particle rotation. This work provides a novel idea for the design of ultra-sensitive sensors and resonators. It has promising applications in optical communication, optical microscopy, and optical signal processing.

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Resonance scattering generated by rotating bodies

Li,

Tang,

Wei

et al. 2024

Phys. Scr.

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Light focusing of aluminium film-coated capsule-shaped particles with penetrated cylinder

Wu,

Zhu,

et al. 2024

J. Opt.

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Microsphere-assisted imaging technology has proven to be a powerful tool for breaking through the Abbe diffraction limit. Appropriate innovation of microsphere structures is of great significance for the design of microlenses. In this paper, a micro-cylinder was added to the center of the microsphere covered with a patchy aluminum film to form a patchy capsule-shaped particle model. The finite difference time domain simulation (FDTD) method was used to simulate the light field. The research model can effectively improve the relevant parameters of focused beams of various structures (photonic nanojet (PNJ), photonic hook (PH), S-shaped photonic hook. In particular, the effective length can be doubled. By changing the position of the patchy aluminum film, the conversion between PNJ, PH and S-shaped PH can be achieved. By changing the height of the central cylinder, a narrower S-shaped PH and more S-shaped PH inflection points can be produced. This work is expected to have potential applications in the fields of nanolithography, super-resolution imaging, light harvesting, micromachining and other fields.

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