Document Type
Article
Publication Date
1-21-2019
Abstract
We employ a genetic algorithm coupled with Mie theory to optimize the magnetic field intensity profile of photonic nanojets (PNJs) generated by multilayer microcylinders at visible wavelengths in free space. We first optimize five-layer microcylinders to elongate the PNJs. We show that a properly designed five-layer microcylinder structure can generate an ultra-long PNJ with a beam length ∼ 107.5 times the illumination wavelength λ0. We then optimize five-layer microcylinders to narrow the waist of PNJs. We show that a PNJ with a full-width at half maximum waist of ∼ 0.22λ0 can be obtained outside the surface of the optimized microcylinder. In addition, curved PNJs with subwavelength waist are also obtained. We finally optimize the five-layer structures for refractive index sensing based on the beam length of PNJs. The estimated minimum detectable refractive index variation when using this sensing method is ultra-small. Our results could potentially contribute to the development of a new generation of devices for optical nanoscopy and biophotonics, and greatly promote the practical applications of PNJs.
Publication Source (Journal or Book title)
Optics Express
First Page
1310
Last Page
1325
Recommended Citation
Huang, Y., Zhen, Z., Shen, Y., Min, C., & Veronis, G. (2019). Optimization of photonic nanojets generated by multilayer microcylinders with a genetic algorithm. Optics Express, 27 (2), 1310-1325. https://doi.org/10.1364/OE.27.001310
