Multi-wavelength unidirectional forward scattering properties of the arrow-shaped gallium phosphide nanoantenna

Journal of the Optical Society of America Pub Date : 2023-10-19 DOI:10.1364/josaa.496501

Jingwei Lv, Yanru Ren, Debao Wang, Xinchen Xu, Wei Liu, Jianxin Wang, Chao Liu, Paul Chu

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Abstract

An arrow-shaped gallium phosphide nanoantenna exhibits both near-field electric field enhancement and far-field unidirectional scattering, and the interference conditions involve electric and magnetic quadrupoles as well as toroidal dipoles. By using long-wavelength approximation and exact multipole decomposition, the interference conditions required for far-field unidirectional transverse light scattering and backward near-zero scattering at multiple wavelengths are determined. The near-field properties are excellent, as exemplified by large Purcell factors of 4.5×10 9 for electric dipole source excitation, 464.68 for magnetic dipole source excitation, and 700 V/m for the field enhancement factor. The degree of enhancement of unidirectional scattering is affected by structural parameters such as the angle and thickness of the nanoantenna. The arrow-shaped nanoantenna is an efficient platform to enhance the electric field and achieve high directionality of light scattering. Moreover, the nanostructure enables flexible manipulation of light waves and materials, giving rise to superior near-field and far-field performances, which are of great importance pertaining to the practicability and application potential of optical antennas in applications such as spectroscopy, sensing, displays, and optoelectronic devices.

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箭头形磷化镓纳米天线的多波长单向正向散射特性

箭头形状的磷化镓纳米天线表现出近场电场增强和远场单向散射，干扰条件包括电、磁四极子和环向偶极子。利用长波长近似和精确多极分解，确定了多波长远场单向横向光散射和后向近零散射所需的干扰条件。近场性能优异，电偶极源激发的Purcell因子为4.5×10 9，磁偶极源激发的Purcell因子为464.68，场增强因子为700 V/m。单向散射增强的程度受纳米天线的角度和厚度等结构参数的影响。箭头形纳米天线是增强电场和实现高方向性光散射的有效平台。此外，纳米结构可以灵活地操纵光波和材料，从而产生优越的近场和远场性能，这对于光学天线在光谱学、传感、显示和光电器件等应用中的实用性和应用潜力具有重要意义。

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Journal of the Optical Society of America

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期刊介绍： OSA was published by The Optical Society from January 1917 to December 1983 before dividing into JOSA A: Optics and Image Science and JOSA B: Optical Physics in 1984.