A polyimide luminescent material, a preparation method, and a used thereof are disclosed; the polyimide luminescent material includes a polyimide resin and a rare earth complex distributed in the polyimide resin, wherein the polyimide resin is a condensation polymer of an aromatic diamine containing a bidentate chelate ligand and an aromatic dianhydride, and the rare earth complex and the bidentate chelate ligand are connected by a chemical bond. The luminescent material has enhanced fluorescence intensity, thermal stability, and mechanical properties. The preparation method is simple and easy, and is suitable for industrial production.

The present application discloses novel azamacrocyclic lanthanide chelate design (Formula (I)) having substituted 4-(phenylethynyl)pyridine chromophores around an emitting lanthanide core, e.g. an europium(III) ion. The chromophores exhibit high molar absorptivity and luminescence with lanthanide ions. The application also discloses a detectable molecule comprising a biospecific binding reagent conjugated to the luminescent chelate, luminescent lanthanide chelating ligand as well as a solid support conjugated with the chelates and their use in various assays.

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The invention relates to scintillation inorganic oxide single crystals with garnet structure, which comprise cerium and are co-alloyed with titanium and Group 2 elements. The invention makes it possible to increase the scintillation output and to enhance the energy resolution of scintillation detectors during gamma-ray quantum registration. The technical result is achieved by a single crystal with a garnet structure being co-alloyed with cerium, titanium and Group 2 elements. This single crystal is produced by the Czochralski process.

The embodiments provide a fluorescent rare earth complex having strong emission intensity and excellent durability, and also provide a security medium using the complex. The rare earth complex according to the embodiment comprises a rare earth ion, a diphosphine dioxide ligand and a β-diketone ligand wherein two phosphorus atoms contained in the diphosphine dioxide ligand individually have substituents different from each other.

Optical tags provide a way to identify assets quickly and unambiguously, an application relevant to anti-counterfeiting and protection of valuable resources or information. The present invention is directed to a tag fluorophore that encodes multilayer complexity in a family of heterometallic rare-earth metal-organic frameworks (RE-MOFs) based on highly connected polynuclear clusters and carboxylic acid-based linkers. Both overt (visible) and covert (near infrared, NIR) properties with concomitant multi-emissive spectra and tunable luminescence lifetimes impart both intricacy and security. Tag authentication can be validated with a variety of orthogonal detection methodologies. The relationships between structure, composition, and optical properties of the family of RE-MOFs can be used to create a large library of rationally designed, highly complex, difficult to counterfeit optical tags.

The present application provides ligands and fluorescent or luminescent complexes comprising these ligands.

The disclosure features methods of analyzing a fluid extracted from a reservoir, the methods including introducing a first composition featuring a first complexing agent into a reservoir at a first location, extracting a fluid from the reservoir at a second location different from the first location, combining the fluid with a second composition featuring a concentration of a lanthanide ion to form a third composition featuring a concentration of a complex formed by the first complexing agent and the lanthanide ion, exposing a quantity of the complex to electromagnetic radiation for a first time period ending at a time t.sub.0, detecting fluorescence emission from the quantity of the complex for a second time period starting at a time t.sub.1>t.sub.0, where t.sub.1−t.sub.0 is greater than 2 microseconds, and determining information about a fluid flow path between the first location and the second location.

The present disclosure provides encoded chromophoric polymer particles that are capable of, for example, optical and/or biomolecular encoding of analytes. The present disclosure also provides suspensions comprising a plurality of encoded chromophoric polymer particles. The present disclosure also provides methods of using the encoded chromophoric polymer particles and systems for performing multiplex analysis with encoded chromophoric polymer particles.

The present disclosure relates to an organic electroluminescent compound comprising a ligand represented by formula 1, and an organic electroluminescent device comprising the same. The organic electroluminescent device having a luminescent efficiency higher than a conventional organic electroluminescent device can be provided by comprising the organic electroluminescent compound of the present disclosure.

Scintillant-doped polystyrene core nanoparticles surrounded by a silica shell can be used to quantify low-energy radionuclides. The nanoparticles are recoverable and re-useable, which may reduce waste and allow for sample recovery. Unlike traditional liquid scintillation cocktail (LSC) formulations, the nanoparticles are made from non-toxic and non-volatile components, and can be used without the aid of surfactants, making them a possible alternative to LSC for reducing the environmental impact of studies that employ radioactive tracers. Recognition elements attached to the functionalized silica surfaces of the nanoparticles allow for separation-free scintillation proximity assay (SPA) applications in aqueous samples. Lipid membrane coatings deposited on the nanoparticle surface can significantly reduce the non-specific adsorption of proteins and other biomolecules, and allow for the incorporation of membrane proteins or other membrane associated binding molecules.