A witness material for monitoring an environmental history of an object may include a material containing a dye of a type that fluoresces in response to actinic radiation in one or both of a shift in color and a change in intensity when subjected to a predetermined stress above a predetermined level; and the material forming a coating on one or more of an outer container for the object, an inner container for the object, a tape that is applied to an outer container for the object, a tape that is applied to an inner container for the object, a shrink wrap enclosing the object, an outer surface of the object, and an inner surface of the object.

An apparatus and method of inline measurement of low-concentration hydrocarbons overlaps fluorescence, scatter and absorption spectroscopy devices so as to measure scatter and absorption of fluorescing oil and the excited fluorescence itself. The apparatus includes a fitting, an input port, an output port, and a sapphire tube having a hollow interior in fluid connection with the input port and the output port. Flow medium passes through the input port, the sapphire tube, and the output port. The apparatus also includes a light emitter, a first detector, and a second detector. The light emitter can include a lens, an absorption and scatter wavelength emitter, and a fluorescence wavelength emitter. An incident absorption and scatter beam and an incident fluorescence beam from the light emitter and parallel so as to determine free hydrocarbon, dissolved hydrocarbons, and solids in a sample within the sapphire tube.

A target substance detection method includes forming a complex by causing a target substance and a dielectric particle to bind to each other, the dielectric particle being modified with a substance having a property of specifically binding to the target substance; separating the complex and an unbound particle from each other in a liquid by dielectrophoresis, the unbound particle being a dielectric particle not constituting the complex; and detecting the target substance included in the separated complex by using an imaging element.

In one embodiment, an apparatus includes a wavelength-shifting element configured to receive an input-light signal. The wavelength-shifting element includes a wavelength-shifting material configured to absorb at least a portion of the received input-light signal and produce an emitted-light signal from the absorbed portion of the received input-light signal. The apparatus also includes a plasmonic grating comprising a plurality of plasmonic-grating elements configured to receive at least a portion of the emitted-light signal and direct the received portion of the emitted-light signal onto a photodetector. The apparatus further includes the photodetector configured to receive the directed portion of the emitted-light signal and produce an electrical current corresponding to the directed portion of the emitted-light signal.

System for visualization of conformal contact. The system visualizes conformal contact between a patterned stamp and a transparent impression surface. A patterned stamp is provided that includes a fluorescent structure for contact with the impression surface. A source of UV light is provided for transmission through the transparent impression surface to interact with the fluorescent structure to generate visible light re-emitted by the fluorescent structure. An imaging system captures the visible light to form a high-contrast image of an area of conformal contact between the patterned stamp and the impression surface. The high-contrast image comprises bright and dark regions representing contact and no contact respectively.

Authentication systems for products employing populations containing particles of diamonds that have fluorescent emissions of various wavelengths, intensities and durations are described. By varying the populations of diamond particles in products to be labeled, multiple different identification systems can be obtained permitting authentication taggants for large numbers of different products.

A method of applying a contrast agent, such as a luminescent contrast agent (e.g. fluorescent, phosphorescent) to the tooth flank surfaces (3, 4) of a gearset (1, 2) wherein the luminescent contrast agent is mixed with transmission oil and is preferably invisible to the human eye. While the members of the gearset roll together, the contrast agent-oil mixture (6) is first introduced into the mesh of the rolling gears. While the mixture is squeezed through the tooth contact, most of the oil is removed in the area of tooth contact. A camera (15), including, as necessary, a filter for certain light wave frequencies, obtains an image which shows the areas with and without luminescent contrast agent. The area (10) where the luminescent contrast agent has been partially or completely removed represents the zone of the tooth contact.

A three-dimensional (3D) object scanning method includes: controlling, when an invisible light source is off, a first camera device to capture a first image of the target object; and controlling, when the invisible light source is on, a second camera device to capture second images of the target object from a plurality of viewing angles. The target object is painted with invisible markers that are invisible to the first camera device when the invisible light source is off. The invisible markers are visible to the second camera device upon absorbing a light emitted by the invisible light source. The second images are used to determine 3D information of the target object.

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.

A polymer comprising a polymer chain moiety and a copper complex moiety (1) is useful as a mechanoresponsive luminescent material. R.sub.1 and R.sub.2 are linking groups to the polymer chain moiety; R.sub.3 to R.sub.6 are H or substituent. ##STR00001##