Abstract: The disclosure relates to a quantum dot light-emitting diode and a fabricating method thereof. The quantum dot light-emitting diode includes a quantum dot layer and an electron transport layer formed on the quantum dot layer. A surface of a side of the quantum dot layer close to the electron transport layer bonds to an ester substance.

Abstract: A quantum dot and its preparation method and application. The method includes the steps of forming a compound quantum dot core first, then adding a precursor of a metal element M2 to be alloyed into the reaction system containing the compound quantum dot core. The metal element M2 undergoes cation exchange with a metal element M1 in the existing compound quantum dot core, thereby forming a quantum dot with an alloy core. In this method, the distribution of alloyed components is not only adjusted by changing the feeding ratio of the metal elements and the non-metal elements, but also by a more real-time, more direct, and more precise adjustments through various reaction condition parameters of the actual reaction process, thereby achieving a more precise composition and energy level distribution control for alloyed quantum dots.

Abstract: A quantum dot film includes: one surface grafted with a first ammonium halide ligand; and another surface opposite to the one surface and grafted with a second ammonium halide ligand. The first ammonium halide ligand has a general structural formula: and the second ammonium halide ligand has a general structural formula: n1?12, n2?12, 12?n3?17, 12?n4?17, n1, n2, n3 and n4 are natural numbers, Y1 and Y2 are independently selected from phenyl or hydrogen, and X is halogen.

Abstract: The present application discloses a method for modifying zinc oxide nanoparticles, comprising following steps: obtaining zinc oxide solution and betaine ligands; mixing the zinc oxide solution and the betaine ligand, keeping a resulting mixed solution reacted under a protective gas atmosphere at a preset temperature, and separating a modified zinc oxide from the resulting mixed solution to obtain a modified zinc oxide. The method for modifying zinc oxide nanoparticles provided in the present application is simple and quick to operate, suitable for industrial production and meets application requirements. And the modified zinc oxide with betaine ligands grafted on the surface has good stability and excellent monodisperse performance, hinders the transmission rate of electrons to a certain extent and improves the recombination efficiency of electrons and holes in the quantum dot light-emitting layer.

Abstract: A composite material, a preparation method thereof, and a quantum dot light-emitting diode. The composite material includes n-type metal oxide nanoparticles and an organic molecule shown in Formula I connected to the n-type metal oxide nanoparticles, and the organic molecule is bound on the surface of the n-type metal oxide nanoparticles through carboxyl groups. In Formula I, R is a hydrocarbyl group or a hydrocarbyl derivative containing at least one conjugation effect unit. The composite material has good film-forming quality and crystalline properties, and enhances the electron mobility of the composite material through conjugation efficiency, thereby having good electron transportation capability.

Abstract: A method for preparing a composite material, including the following steps: providing metal oxide nanoparticles and a polyaromatic compound having a structure represented by Formula I, where, Ar1, Ar2, Ar3, and Ar4 are selected from aromatic rings; X1, X2, and X3 are selected from active groups configured for binding with the metal oxide nanoparticles, each of R1, R2, and R3 independently contains at least one of alkylene, amine, —N?N—, alkenyl, alkynyl, and phenyl, and each of m, n, and y is independently selected from 0 or positive integers; dispersing the polyaromatic compound and the metal oxide nanoparticles in a solvent to yield a mixed solution; and heating the mixed solution to yield the composite material. A composite material includes: a polyaromatic compound and metal oxide nanoparticles. The polyaromatic compound is connected to the metal oxide nanoparticles. The polyaromatic compound has a structure represented by Formula I.

Abstract: The present application discloses a composite and its preparation method and application. The composite includes silica-coated quantum dots and graphene nanosheets on the surface of the silica-coated quantum dots; wherein the silica-coated quantum dots include quantum dots and silica layer coated on the surface of the quantum dots. And the graphene nanosheets and the silica layer is bonded by (O—)3Si—R1—NHCO—R3—CONH—R2—Si(O—)3 or (O—)3Si—R4—SCH2CH2—R5—Si(O—)3, R1, R2, R4, R5 are respectively selected from a group consisting of a hydrocarbyl or a hydrocarbyl derivative, R3 is selected from a hydrocarbyl, a hydrocarbyl derivative, an aryl or an aryl derivative. The composite can further improve the stability of quantum dots without affecting the inherent optical properties of quantum dots, thereby improving luminous efficiency.

Abstract: The present disclosure discloses a quantum dot and a preparation method thereof, the method comprises a plurality of following steps: preparing a quantum dot solution; preparing an ion-containing organic ligand precursor; adding the ion-containing organic ligand precursor into the quantum dot solution, and making a surface-modification to the quantum dots, before obtaining the quantum dots having the surfaces modified; or providing a quantum dot solution; providing an ion-containing organic ligand precursor; mixing the ion-containing organic ligand precursor and the quantum dot solution, to make a ligand exchanging, before centrifuging and obtaining the quantum dots having the ligand exchanged.

Abstract: The present disclosure provides a quantum dot. The quantum dot includes a group III-V quantum dot core, and at least one type of halide ions, acetylacetonate ions, or hydroxyl ions bound to a surface of the group III-V quantum dot core, where the halide ions, the acetylacetonate ions and the hydroxyl ions are bound with group III cations on the surface of the group III-V quantum dot core.

Abstract: The present disclosure provides a quantum dot. The quantum dot includes a group III-V quantum dot core, and at least one type of halide ions, acetylacetonate ions, or hydroxyl ions bound to a surface of the group III-V quantum dot core, where the halide ions, the acetylacetonate ions and the hydroxyl ions are bound with group III cations on the surface of the group III-V quantum dot core.

Abstract: A quantum dot and its preparation method and application. The method includes the steps of forming a compound quantum dot core first, then adding a precursor of a metal element M2 to be alloyed into the reaction system containing the compound quantum dot core. The metal element M2 undergoes cation exchange with a metal element M1 in the existing compound quantum dot core, thereby forming a quantum dot with an alloy core. In this method, the distribution of alloyed components is not only adjusted by changing the feeding ratio of the metal elements and the non-metal elements, but also by a more real-time, more direct, and more precise adjustments through various reaction condition parameters of the actual reaction process, thereby achieving a more precise composition and energy level distribution control for alloyed quantum dots.

Abstract: The present application discloses a composite and its preparation method and application. The composite includes silica-coated quantum dots and graphene nanosheets on the surface of the silica-coated quantum dots; wherein the silica-coated quantum dots include quantum dots and silica layer coated on the surface of the quantum dots. And the graphene nanosheets and the silica layer is bonded by (O—)3Si—R1—NHCO—R3—CONH—R2—Si(O—)3 or (O—)3Si—R4—SCH2CH2—R5—Si(O—)3, R1, R2, R4, R5 are respectively selected from a group consisting of a hydrocarbyl or a hydrocarbyl derivative, R3 is selected from a hydrocarbyl, a hydrocarbyl derivative, an aryl or an aryl derivative. The composite can further improve the stability of quantum dots without affecting the inherent optical properties of quantum dots, thereby improving luminous efficiency.

Abstract: The present disclosure discloses a quantum dot and a preparation method thereof, the method comprises a plurality of following steps: preparing a quantum dot solution; preparing an ion-containing organic ligand precursor; adding the ion-containing organic ligand precursor into the quantum dot solution, and making a surface-modification to the quantum dots, before obtaining the quantum dots having the surfaces modified; or providing a quantum dot solution; providing an ion-containing organic ligand precursor; mixing the ion-containing organic ligand precursor and the quantum dot solution, to make a ligand exchanging, before centrifuging and obtaining the quantum dots having the ligand exchanged.