Abstract: A method for separating oil-water two-phase NMR signals by using dynamic nuclear polarization comprising: using a combination of a non-selective free radical and a selective relaxation reagent to selectively enhance an NMR signal of an oil phase or a water phase, the relaxation reagent being capable of selectively suppressing dynamic polarization enhancement of the water phase or oil phase, thus achieving the polarization enhancement of a single fluid phase in the mixed fluid phases and realizing separation of the two-phase signals; or using a selective free radical to selectively enhance the NMR signal of the oil phase or the water phase, thus achieving the polarization enhancement of a single fluid phase in the mixed fluid phases and realizing separation of the oil-water two-phase NMR signals. The method is simple and easy to operate, has a short test time, and can efficiently separate NMR signals of oil and water phases.

Abstract: A ridge recognition substrate and a ridge recognition apparatus. The ridge recognition substrate includes: a base substrate including a photosensitive area, and a light-shielding area located on at least one side of the photosensitive area; a plurality of photosensitive devices, arranged in the photosensitive area in an array; each photosensitive device includes a first electrode, a photoelectric conversion structure and a second electrode arranged in layers, the photoelectric conversion structure is electrically connected with the first electrode, and the photoelectric conversion structure directly contacts with the second electrode; and dummy devices, arranged in the light-shielding area in an array, each dummy device including a third electrode, an equivalent dielectric layer and a fourth electrode, the third electrode and the first electrode is in the same layer, the fourth electrode is located at the side of the layer where the second electrode is located facing away from the base substrate.

Abstract: In a peeling system and a peeling method for a flexible fingerprint component provided by the present invention, the flexible fingerprint component is formed on a rigid substrate, and the flexible fingerprint component comprises a flexible substrate, a photosensitive device layer and an optical film sequentially arranged on the flexible substrate, a first chip-on film bonded to the photosensitive device layer on a first side of the optical film, and a second chip-on film bonded to the photosensitive device layer on a second side of the optical film, wherein the optical film is provided with an extension portion beyond the flexible substrate, the second side of the optical film is located on a side opposite to the extension portion, and the first side of the optical film is located on a side adjacent to the extension portion.

Abstract: An optical sensor array substrate and an optical fingerprint reader are provided. The optical sensor array substrate includes a substrate including a detection area which includes a plurality of photosensitive pixels. Photosensitive pixel includes: a TFT arranged on the substrate; a storage capacitor arranged on the substrate and having a first capacitor plate, and a second capacitor plate electrically connected to the source or drain of the TFT; a photosensitive element, having one end electrically connected to the second capacitor plate; a first electrode layer electrically connected to another end of the photosensitive element. On the substrate, an orthographic projection of the second capacitor plate at least partially overlaps with that of the first electrode layer, and the first capacitor plate is located in the same layer and has the same material as the gate of the TFT.

Abstract: A method for industrially manufacturing large-size graphene comprises following steps: (1) mixing graphite and concentrated sulfuric acid to obtain a mixed liquid, and ultrasonically treating the mixed liquid to obtain an upper layer of graphene and a lower layer of concentrated sulfuric acid liquid under condition that a chemical intercalation and a mechanical stripping were performed simultaneously; (2) separating the upper layer of graphene and the lower layer of concentrated sulfuric acid liquid; (3) the graphene separated in the step (2) being washed with water, filtered, and dried to obtain a large-size graphene. The method has the advantages of good peeling effect, great graphene size, repeated use of sulfuric acid as an intercalating agent, environment-friendliness, resource saving and wide industrial application prospect.

Abstract: A method for industrially manufacturing large-size graphene comprises following steps: (1) mixing graphite and concentrated sulfuric acid to obtain a mixed liquid, and ultrasonically treating the mixed liquid to obtain an upper layer of graphene and a lower layer of concentrated sulfuric acid liquid under condition that a chemical intercalation and a mechanical stripping were performed simultaneously; (2) separating the upper layer of graphene and the lower layer of concentrated sulfuric acid liquid; (3) the graphene separated in the step (2) being washed with water, filtered, and dried to obtain a large-size graphene. The method has the advantages of good peeling effect, great graphene size, repeated use of sulfuric acid as an intercalating agent, environment-friendliness, resource saving and wide industrial application prospect.

Abstract: The present invention provides hydrophilic surface modifying macromolecules (H-phil SMM) and H-phil SMM and blended membranes produced incorporating the hydrophilic surface modifying macromolecules. The membranes include a hydrophilic base polymer, and the hydrophilic surface modifying macromolecules (H-phil SMM) which impart surface hydrophilic properties to the membrane. The membranes produced with the surface modifying macromolecules give polymer membranes useful in the separation of water from a solution containing volatile organic compounds and water.