Inflection point: a perspective on photonic nanojets

When light propagates through the edge or middle part of a microparticle's incoming interface, there is a basic rule that light converges and diverges rapidly or slowly at the output port. These two parts are referred to as the region of rapid change (RRC) and region of slow change (RSC), respectively. Finding the boundary point between RRC and RSC is the key to reveal and expound upon this rule scientifically. Based on the correlation between light convergence-divergence and the slope of emergent light, combined with the relationship between a natural logarithm and growth in physical reality and the second derivative of a function in practical significance, we determine the boundary point between RRC and RSC, namely, the inflection point. From such a perspective, a photonic nanojet (PNJ) and near-field focusing by light irradiation on RSC and RRC, as well as the position of the inflection point under different refractive index contrasts and the field distribution of light focusing, are studied with finite-element-method-based numerical simulation and ray-optics-based theoretical analysis. By illuminating light of different field intensity ratios to the regions divided by the inflection point, we demonstrate the generation of a photonic hook (PH) and the modulation of PNJ/PH in a new manner. (C) 2021 Chinese Laser Press

Automated summary

When light propagates through a microparticle, it converges and diverges rapidly or slowly at the output port, depending on the region of rapid change (RRC) or region of slow change (RSC). The boundary point between these two regions, known as the inflection point, is crucial in understanding this phenomenon. Using numerical simulations and theoretical analysis, studies have been conducted on the position of the photonic nanojet (PNJ) and near-field focusing, as well as the field distribution of light focusing under different refractive index contrasts.