Systems and methods related to optical nanosensors comprising photoluminescent nanostructures are generally described.

Methods and apparatus are presented for measuring a photoluminescence (PL) response, preferably a spatially resolved image of a PL response, from an object exposed to solar irradiation. In certain embodiments signals from the object are measured in two or more different spectral bands selected such that one of the measured signals has a higher PL component relative to ambient reflectance compared to another measured signal, enabling the PL component to be enhanced by a suitable differencing procedure. In other embodiments a signal from an object is measured in a spectral band selected such that at least 20% of the measured signal comprises PL generated from the object by the solar irradiation. The methods and apparatus have particular application to outdoor inspection of photovoltaic modules without having to modulate the operating point of the modules.

The present invention provides for metallic structures comprising a sulfhydryl or amino-terminated hydrophilic coating to provide a layer of hydrophilic character on the surface of the metallic structures thereby allowing the use of low volumes of aqueous solvents of fluorophores that have the ability to “spread out” across the surfaces of the metallic structures and to provide for a more uniform surface coating of fluorophores attached to or near the metallic structures.

Apparatus and methods for the detection of proteins in biological fluids such as urine using a label-free assay is described. Specific proteins are detected by their binding to highly specific capture reagents such as SOMAmers that are attached to the surface of a substrate. Changes to these capture reagents and their local environment upon protein binding modify the behavior of color centers (e.g., fluorescence, ionization state, spin state, etc.) embedded in the substrate beneath the bound capture reagents. These changes can be read out, for example, optically or electrically, for an individual color center or as an average response of many color centers.

The current invention relates to the use of a neural network to improve the quality of images obtained from light scattered by an intermediate object that scatters light, such as tissue or a frosted screen. The invention relates to a method of imaging a human or animal bode using a nanocrystal array capable of fluorescing upon excitation from light from a near-infrared light source. This invention also relates to detection means and apparatus used in said methods, as well as to quantum dots useful in said use.

A method for fabricating a semiconductor device is provided. The method for fabricating the semiconductor device includes forming a semiconductor pattern including a first layer and a second layer on a substrate, forming a coating layer on a surface of the first layer, forming a dyeing substance in which one of an antibody or a protein is combined with a fluorophore, attaching the dyeing substance to a surface of the coating layer to form a dyeing layer, and photographing the fluorophore with an ultra-high resolution microscope to detect the semiconductor pattern.

An inspection apparatus is an inspection apparatus includes an excitation light source that generates excitation light to irradiate the object, a dichroic mirror that separates fluorescence from the sample by transmitting or reflecting the fluorescence according to a wavelength, a camera that images fluorescence reflected by the dichroic mirror, a camera that images fluorescence transmitted through the dichroic mirror, and a control apparatus that derives color irregularity information of a light-emitting element based on a first fluorescence image acquired by the camera and a second fluorescence image acquired by the camera, and an edge shift width corresponding to a width of a wavelength band in which transmittance and reflectance change according to a change in wavelength in the dichroic mirror is wider than a full width at half maximum of a normal fluorescence spectrum of the light-emitting element.

A facet region detection method includes a first irradiation step and a second irradiation step in which a first surface and a second surface, respectively, of an ingot are irradiated with light, and a first fluorescence detection step and a second fluorescence detection step in which distribution of the number of photons of fluorescence in the first surface and the second surface, respectively, is obtained. The facet region detection method further includes a first determination step and a second determination step in which a facet region and a non-facet region are determined in the first surface and the second surface on a basis of the number of photons of the fluorescence, and a calculation step in which an estimated position of a facet region inside the ingot is calculated based on the facet region in the first surface and the facet region in the second surface.

A method of evaluating metal contamination by measuring the amount of metal contaminants to a silicon wafer in a rapid thermal processing apparatus includes steps of obtaining a Si single crystal grown by the Czochralski method at a pulling rate of 1.0 mm/min or lower, the crystal having oxygen concentration of 1.3×10.sup.18 atoms/cm.sup.3 or less, slicing silicon wafers from the Si single crystal except regions of 40 mm toward the central portion from the head of the single crystal and 40 mm toward the central portion from the tail, heat-treating the silicon wafer with a rapid thermal processing apparatus and transferring contaminants from members in a furnace of the rapid thermal processing apparatus to the silicon wafer, and measuring a lifetime of the silicon wafer to which contaminants are transferred.

The present disclosure provides a method for detection of an analyte in a sample, where the sample is introduced into an analytic chamber along with droplets of an emulsion or gel beads. In another aspect, the present disclosure provides designs for formulations of emulsion drops or gel beads such that they are useful for detection of analytes in a massively parallel manner. Formulations that contain specific combinations of fluorescent particles allow optical determination of the identity of each fluorescent particle. The combinations are based on particle fluorescence emission wavelength, fluorescence excitation wavelength, and particle count.