Deep Subwavelength-Scale Light Focusing and Confinement in Nanohole-Structured Mesoscale Dielectric Spheres

One of the most captivating properties of dielectric mesoscale particles is their ability to form a sub-diffraction limited-field localization region, near their shadow surfaces. However, the transverse size of the field localization region of a dielectric mesoscale particle is usually larger than λ/3. In this present paper, for the first time, we present numerical simulations to demonstrate that the size of the electromagnetic field that forms in the localized region of the dielectric mesoscale sphere can be significantly reduced by introducing a nanohole structure at its shadow surface, which improves the spatial resolution up to λ/40 and beyond the solid immersion diffraction limit of λ/2n. The proposed nanohole-structured microparticles can be made from common natural optical materials, such as glass, and are important for advancing the particle-lens-based super-resolution technologies, including sub-diffraction imaging, interferometry, surface fabrication, enhanced Raman scattering, nanoparticles synthesis, optical tweezer, etc.

[1]  Zengbo Wang,et al.  Production of photonic nanojets by using pupil-masked 3D dielectric cuboid , 2017 .

[2]  Zengbo Wang,et al.  Intensity‐Enhanced Apodization Effect on an Axially Illuminated Circular‐Column Particle‐Lens , 2018 .

[3]  M. Lipson,et al.  Electrically driven silicon resonant light emitting device based on slot-waveguide. , 2005, Optics express.

[4]  Lihong V. Wang,et al.  Ultralong photonic nanojet formed by a two-layer dielectric microsphere. , 2014, Optics letters.

[5]  Y. Kivshar,et al.  Engineering scattering patterns with asymmetric dielectric nanorods. , 2018, Optics express.

[6]  Daniel R. Mason,et al.  Enhanced resolution beyond the Abbe diffraction limit with wavelength-scale solid immersion lenses. , 2010, Optics letters.

[7]  Martin A M Gijs,et al.  Super-Resolution Imaging of a Dielectric Microsphere Is Governed by the Waist of Its Photonic Nanojet. , 2016, Nano letters.

[8]  Yuchao Li,et al.  Trapping and Detection of Nanoparticles and Cells Using a Parallel Photonic Nanojet Array. , 2016, ACS nano.

[9]  J. F. Wu,et al.  Modulation of photonic nanojets generated by microspheres decorated with concentric rings. , 2015, Optics express.

[10]  Zengbo Wang,et al.  Refractive index less than two: photonic nanojets yesterday, today and tomorrow [Invited] , 2017 .

[11]  Hervé Rigneault,et al.  Direct imaging of photonic nanojets. , 2008, Optics express.

[12]  Igor V. Minin,et al.  Engineering photonic nanojet by a graded-index micro-cuboid , 2018 .

[13]  J. Holzman,et al.  Integration of photonic nanojets and semiconductor nanoparticles for enhanced all-optical switching , 2015, Nature Communications.

[14]  J. Qu,et al.  Overstepping the upper refractive index limit to form ultra-narrow photonic nanojets , 2017, Scientific Reports.

[15]  A. Taflove,et al.  Photonic nanojets , 2004, IEEE Antennas and Propagation Society Symposium, 2004..

[16]  Qianfan Xu,et al.  Guiding and confining light in void nanostructure. , 2004, Optics letters.

[17]  Igor V. Minin,et al.  Diffractive Optics and Nanophotonics: Resolution Below the Diffraction Limit , 2015 .

[18]  Miguel Beruete,et al.  Subwavelength, standing-wave optical trap based on photonic jets , 2016 .

[19]  P. Latimer Light scattering by a structured particle: the homogeneous sphere with holes. , 1984, Applied optics.