20 research outputs found
Equivalence of reflection paths of light and Feynman paths in stacked metasurfaces
We show the existence of virtual polarization states during the interaction of modes in metasurface stacks. In support of our findings we experimentally realize a metasurface stack, consisting of an isotropic layer of nanopatches and an anisotropic layer of nanowires. Utilizing an analogy to the interaction of electrons at junctions in mesoscopic electron transport via Feynman paths, we present a semi-analytic description of the modal interaction inside this stack. We then derive a series of all possible reflection paths light can take inside the metasurface stack
Nanostructure-modulated planar high spectral resolution spectro-polarimeter
We present a planar spectro-polarimeter based on Fabry-P{\'e}rot cavities
with embedded polarization-sensitive high-index nanostructures. A
m-thick spectro-polarimetric system for 3 spectral bands and 2 linear
polarization states is experimentally demonstrated. Furthermore, an optimal
design is theoretically proposed, estimating that a system with a bandwidth of
127~nm and a spectral resolution of 1~nm is able to reconstruct the first three
Stokes parameters \textcolor{black}{with a signal-to-noise ratio of -13.14~dB
with respect to the the shot noise limited SNR}. The pixelated
spectro-polarimetric system can be directly integrated on a sensor, thus
enabling applicability in a variety of miniaturized optical devices, including
but not limited to satellites for Earth observation
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Laser-induced spatially-selective tailoring of high-index dielectric metasurfaces
Optically resonant high-index dielectric metasurfaces featuring Mie-type electric and magnetic resonances are usually fabricated by means of planar technologies, which limit the degrees of freedom in tunability and scalability of the fabricated systems. Therefore, we propose a complimentary post-processing technique based on ultrashort (= 10 ps) laser pulses. The process involves thermal effects: crystallization and reshaping, while the heat is localized by a high-precision positioning of the focused laser beam. Moreover, for the first time, the resonant behavior of dielectric metasurface elements is exploited to engineer a specific absorption profile, which leads to a spatially-selective heating and a customized modification. Such technique has the potential to reduce the complexity in the fabrication of non-uniform metasurface-based optical elements. Two distinct cases, a spatial pixelation of a large-scale metasurface and a height modification of metasurface elements, are explicitly demonstrated. © 2020 Optical Society of America under the terms of the OSA Open Access Publishing Agreemen
Toward perfect optical diffusers: dielectric huygensâ metasurfaces with critical positional disorder
Conventional optical diffusers, such as thick volume scatterers (Rayleigh scattering) or microstructured surface scatterers (geometric scattering), lack the potential for onâchip integration and are thus incompatible with nextâgeneration photonic devices. Dielectric Huygensâ metasurfaces, on the other hand, consist of 2D arrangements of resonant dielectric nanoparticles and therefore constitute a promising material platform for ultrathin and highly efficient photonic devices. When the nanoparticles are arranged in a random but statistically specific fashion, diffusers with exceptional properties are expected to come within reach. This work explores how dielectric Huygensâ metasurfaces can implement wavelengthâselective diffusers with negligible absorption losses and nearly Lambertian scattering profiles that are largely independent of the angle and polarization of incident waves. The combination of tailored positional disorder with a carefully balanced electric and magnetic response of the nanoparticles is shown to be an integral requirement for the operation as a diffuser. The proposed metasurfacesâ directional scattering performance is characterized both experimentally and numerically, and their usability in wavefrontâshaping applications is highlighted. Since the metasurfaces operate on the principles of Mie scattering and are embedded in a glassy environment, they may easily be incorporated in integrated photonic devices, fiber optics, or mechanically robust augmented reality displays
Investigation of dipole emission near a dielectric metasurface using a dual-tip scanning near-field optical microscope
A wide variety of near-field optical phenomena are described by the interaction of dipole radiation with a nanophotonic system. The electromagnetic field due to the dipole excitation is associated with the Greenâs function. It is of great interest to investigate the dipole interaction with a photonic system and measure the near-field Greenâs function and the quantities it describes, e.g., the local and cross density of optical states. However, measuring the near-field Greenâs function requires a point-source excitation and simultaneous near-field detection below the diffraction limit. Conventional single-tip near-field optical microscope (SNOM) provides either a point source excitation or amplitude and phase detection with subwavelength spatial resolution. The automated dual-tip SNOM, composed of two tips, has overcome the experimental challenges for simultaneous near-field excitation and detection. Here, we investigate the dipole emission in the near-field of a dielectric metasurface using the automated dual-tip SNOM. We have analyzed the near-field pattern and directional mode propagation depending on the position of the dipole emission relative to the metasurface. This study is one further step toward measuring the dyadic Greenâs function and related quantities such as cross density of optical states in complex nanophotonic systems for both visible and near-infrared spectra
Towards Perfect Optical Diffusers: Dielectric Huygens\u27 Metasurfaces with Critical Positional Disorder
4âČ-Amino-benzamido-taurocholic Acid Selectively Solubilizes Glycosyl-phosphatidylinositol-Anchored Membrane Proteins and Improves Lipolytic Cleavage of Their Membrane Anchors by Specific Phospholipases
Glycosyl-phosphatidylinositol-anchored membrane proteins (GPI-proteins) are normally identified either by cleavage of the lipid anchor using (glycosyl)phosphatidylinositol-specific phospholipases C or D (GPI-PLs) or by metabolic labeling of the lipid moiety with specific building blocks. Therefore, methods for discrimination between transmembrane proteins and GPI-proteins on the basis of their physicochemical properties are desirable. Here we are presenting a selective extraction method for typical well-characterized mammalian GPI-proteins, e.g., acetylcholine esterase, alkaline phosphatase, 5âČ-nucleotidase, and lipoprotein lipase, using a derivative of taurocholate. The results were compared to those obtained with well-characterized transmembrane proteins, e.g., insulin receptor and hydroxymethyl glutaryl coenzyme A-reductase, glucose transporters, or aminopeptidase M and several commercially available detergents. With regard to total membrane proteins, it was possible to selectively enrich GPI-proteins up to 8- to 14-fold by using concentrations between 0.1 and 0.3% of 4âČ-NH2-amino-7ÎČ-benzamido-taurocholic acid (BATC). In addition, the cleavage specificity and efficiency of (G)PI-PLs were increased in the presence of identical concentrations of BATC compared to commonly used detergents, e.g., Nonidet P-40. Therefore, the present study shows that the use of BATC facilitates the identification of glycosyl-phosphatidylinositol-anchored membrane proteins