Light-sample interaction in microsphere enhanced 2D super-resolution imaging

Show full item record



Permalink

http://hdl.handle.net/10138/314821

Citation

Maconi , G , Kassamakov , I , Vainikka , T , Arstila , T & Haeggstrom , E 2019 , Light-sample interaction in microsphere enhanced 2D super-resolution imaging . in P Lehmann , W Osten & A A Gonçalves Jr. (eds) , Optical Measurement Systems for Industrial Inspection XI . Proceedings of SPIE , vol. 11056 , SPIE - the international society for optics and photonics , Bellingham, WA , Optical Measurement Systems for Industrial Inspection , München , Germany , 24/06/2019 . https://doi.org/10.1117/12.2525489

Title: Light-sample interaction in microsphere enhanced 2D super-resolution imaging
Author: Maconi, Goran; Kassamakov, Ivan; Vainikka, T.; Arstila, Timo; Haeggstrom, Edward
Other contributor: University of Helsinki, Materials Physics
University of Helsinki, Department of Physics
University of Helsinki, Department of Physics
Lehmann, Peter
Osten, Wolfgang
Gonçalves Jr., Armando Albertazzi

Publisher: SPIE - the international society for optics and photonics
Date: 2019
Language: eng
Number of pages: 7
Belongs to series: Optical Measurement Systems for Industrial Inspection XI
Belongs to series: Proceedings of SPIE
ISBN: 978-1-5106-2791-8
978-1-5106-2792-5
DOI: https://doi.org/10.1117/12.2525489
URI: http://hdl.handle.net/10138/314821
Abstract: We simulate the image generated by a microsphere residing in contact on top of an exposed Blu-ray disk surface, when observed by a conventional microscope objective. While microsphere lenses have been used to focus light beyond the diffraction limit and to produce super-resolution images, the nature of the light-sample interaction is still under debate. Simulations in related articles predict the characteristics of the photonic nanojet (PNJ) formed by the microsphere, but so far, no data has been published on the image formation in the far-field. For our simulations, we use the open source package Angora and the commercial software RSoft FullWave. Both packages implement the Finite Difference Time Domain (FDTD) approach. Angora permits us to accurately simulate microscope imaging at the diffraction limit. The RSoft FullWave is able to record the steady-state complex electrical and magnetic fields for multiple wavelengths inside the simulation domain. A microsphere is simulated residing on top of a dielectric substrate featuring sub-wavelength surface features. The scattered light is recorded at the edges of the simulation domain and is then used in the near-field to far-field transformation. The light in the far field is then refocused using an idealized objective model, to give us the simulated microscope image. Comparisons between the simulated image and experimentally acquired microscope images verify the accuracy of our model, whereas the simulation data predicts the interaction between the PNJ and the imaged sample. This allows us to isolate and quantify the near-field patterns of light that enable super-resolution imaging, which is important when developing new micro-optical focusing structures.
Subject: Super-resolution imaging
FDTD
simulation
Near-field optics
Photonic nanojet
114 Physical sciences
Rights:


Files in this item

Total number of downloads: Loading...

Files Size Format View
SPIE_2019_maconi_superresolution_v2_gm.pdf 378.7Kb PDF View/Open

This item appears in the following Collection(s)

Show full item record