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Source: Patrick Robert Gill, Changhyuk Lee, Dhon-Gue Lee, Albert Wang, Alyosha Molnar, "A microscale camera using direct Fourier-domain scene capture," Opt. Lett. 36(15) 2949-2951 (2011); http://www.osapublishing.org/ol/abstract.cfm?URI=ol-36-15-2949 Caption: Decomposition of natural images into Fourier components. (a) All images can be expressed as a sum of 2D Fourier basis functions [e.g., (b)] by taking the sum over all values in (c) the basis-scaled image.	Source: Alison M. Yao, Miles J. Padgett, "Orbital angular momentum: origins, behavior and applications," Adv. Opt. Photon. 3(2) 161-204 (2011); http://www.osapublishing.org/aop/abstract.cfm?URI=aop-3-2-161 Caption: Ghost imaging: coincidence measurements of two beams of entangled photons—one of which interacts with an object and one of which doesn’t—can be used to reconstruct a “ghost” image of the object.	Source: Michael J. Murdoch, Ingrid E. J. Heynderickx, "Veiling glare and perceived black in high dynamic range displays," J. Opt. Soc. Am. A 29(4) 559-566 (2012); http://www.osapublishing.org/josaa/abstract.cfm?URI=josaa-29-4-559 Caption: Source images used in the experiment. Upper, L-R: cosine, cosine2, curls. Lower, L-R: eye, nose, palm. Each image was presented at a size of two degrees of visual angle square.	$4 Liquid-crystal SLMs allow unprecedented control in the generation and detection of structured light fields. (a) Long exposure image of laser light diffracted from the pixelated device. (b) CCD camera image showing the various diffraction orders. Efficiencies are typically in the 60%–85% range.$ Source: Andrew Forbes, Angela Dudley, Melanie McLaren, "Creation and detection of optical modes with spatial light modulators," Adv. Opt. Photon. 8(2) 200-227 (2016); http://www.osapublishing.org/aop/abstract.cfm?URI=aop-8-2-200 Caption: Liquid-crystal SLMs allow unprecedented control in the generation and detection of structured light fields. (a) Long exposure image of laser light diffracted from the pixelated device. (b) CCD camera image showing the various diffraction orders. Efficiencies are typically in the 60%–85% range.
Source: Natan T. Shaked, Lisa L. Satterwhite, Nenad Bursac, Adam Wax, "Whole-cell-analysis of live cardiomyocytes using wide-field interferometric phase microscopy," Biomed. Opt. Express 1(2) 706-719 (2010); http://www.osapublishing.org/boe/abstract.cfm?URI=boe-1-2-706 Caption: WFDI-based phase profile of a cardiomyocyte during a single beating cycle, 40 × . White horizontal scale bar represents 10 µm. Vertical color bar is in radians. Dynamics, 120 fps for 1 sec: Media 3.	Source: Andreas Rottler, Stephan Schwaiger, Aune Koitmäe, Detlef Heitmann, Stefan Mendach, "Transmission enhancement in three-dimensional rolled-up plasmonic metamaterials containing optically active quantum wells," J. Opt. Soc. Am. B 28(10) 2402-2407 (2011); http://www.osapublishing.org/josab/abstract.cfm?URI=josab-28-10-2402 Caption: Sketch of a microroll that can be fabricated by rolling up strained layers. The tube wall represents a three- dimensional metamaterial consisting of a metal–semiconductor superlattice containing quantum wells and metal gratings.	Source: H. Subramanian, P. Viswanathan, L. Cherkezyan, R. Iyengar, S. Rozhok, M. Verleye, J. Derbas, J. Czarnecki, H. K. Roy, V. Backman, "Procedures for risk-stratification of lung cancer using buccal nanocytology," Biomed. Opt. Express 7(9) 3795-3810 (2016); http://www.osapublishing.org/boe/abstract.cfm?URI=boe-7-9-3795 Caption: Examples of buccal squamous epithelial cells found on prepared specimen slides. (a) Representative transmission image of two overlapping cells and (d) the corresponding spatially resolved map Σ(x, y) calculated by PWS. (b) Example of a folded isolated cell and (e) the corresponding map of Σ. (c) Isolated, non-folded cell classified as “suitable” for our study and (f) the corresponding Σ(x, y).	Source: Nicolai Granzow, Patrick Uebel, Markus A. Schmidt, Andrey S. Tverjanovich, Lothar Wondraczek, Philip St. J. Russell, "Bandgap guidance in hybrid chalcogenide–silica photonic crystal fibers," Opt. Lett. 36(13) 2432-2434 (2011); http://www.osapublishing.org/ol/abstract.cfm?URI=ol-36-13-2432 Caption: (a) Schematic of chalcogenide–silica all-solid bandgap fiber. Red: chalcogenide strands. (b) Scanning electron micrograph of endface of a chalcogenide–silica bandgap fiber (core diameter 7.6 μm , pitch 3.8 μm , hole diameter 1.45 μm ) polished by focused-ion-beam milling.
$9 Phase distribution of the diffraction pattern observed at z ∕ L = 2.0 , caused by a finite-radius SPP with fractional topological charge α = 2.5 . We can see the chain of unit strength vortices on the + x axis.$ Source: Hipolito Garcia-Gracia, Julio C. Gutiérrez-Vega, "Diffraction of plane waves by finite-radius spiral phase plates of integer and fractional topological charge," J. Opt. Soc. Am. A 26(4) 794-803 (2009); http://www.osapublishing.org/josaa/abstract.cfm?URI=josaa-26-4-794 Caption: Phase distribution of the diffraction pattern observed at z ∕ L = 2.0 , caused by a finite-radius SPP with fractional topological charge α = 2.5 . We can see the chain of unit strength vortices on the + x axis.	Source: Jin Hou, Jiajia Zhao, Chunyong Yang, Zhiyou Zhong, Yihua Gao, Shaoping Chen, "Engineering ultra-flattened-dispersion photonic crystal fibers with uniform holes by rotations of inner rings," Photon. Res. 2(2) 59-63 (2014); http://www.osapublishing.org/prj/abstract.cfm?URI=prj-2-2-59 Caption: Fundamental mode transverse electric field intensity (Et2) distributions at 1.45 μm (upper figures) and 1.75 μm (lower figures) wavelengths, for nearly zero-dispersion flattened PCFs with Λ=2.3 μm and d=0.61 μm for (a) α=0° and β=0°, (b) α=30° and β=0°, (c) α=0° and β=30°, (d) α=0° and β=0°, (e) α=30° and β=0°, and (f) α=0° and β=30°.	Source: Maciej Antkowiak, Maria Leilani Torres-Mapa, Kishan Dholakia, Frank J. Gunn-Moore, "Quantitative phase study of the dynamic cellular response in femtosecond laser photoporation," Biomed. Opt. Express 1(2) 414-424 (2010); http://www.osapublishing.org/boe/abstract.cfm?URI=boe-1-2-414 Caption: Comparison of quantitative phase maps with fluorescent assays during an optoinjection experiment: a) phase map and b) propidium iodide fluorescence (optoinjection assay) 5 min after irradiation ; c) phase map and d) Calcein AM fluorescence (viability assay) after 90 min incubation. Two cells were successfully optoinjected - one proved viable (solid arrow) while the other (dashed arrow) was necrotic after 90 min. Note the significant decrease in the optical thickness of the non-viable cell. Scale bars 20 μm.	Source: X. F. Meng, X. Peng, L. Z. Cai, A. M. Li, J. P. Guo, Y. R. Wang, "Wavefront reconstruction and three-dimensional shape measurement by two-step dc-term-suppressed phase-shifted intensities," Opt. Lett. 34(8) 1210-1212 (2009); http://www.osapublishing.org/ol/abstract.cfm?URI=ol-34-8-1210 Caption: Experimental results using the proposed method: some typical 3-D geometries of the human face mask in wireframe mode.