Abstract:
Provided is a multi-layered composite precursor (2) which includes: a substrate (4) which includes a light-emitting organic compound, a first surface (8), and a second surface (10) which is overlapped by a transparent electroconductive layer; and a liquid phase (18) which overlaps at least a part of the first surface (8) including a metal-organic compound, wherein the metal-organic compound includes an organic moiety which includes a C=O group. The liquid phase (18) further includes a first silicon compound which includes at least one carbon atom and at least one nitrogen atom.
Abstract:
Disclosed is a method for forming a nanostructure using various kinds of solvents. The method for forming the nanostructure using the various kinds of solvents according to one embodiment of the present invention includes: a first step of preparing a first solution by dissolving a first solute in a first solvent; a second step of preparing a second solution by dissolving a second solute in a second solvent; a third step of preparing a hybrid solution by stirring the first solution and the second solution; and a fourth step of forming the nanostructure using the hybrid solution.
Abstract:
나노 입자를 포함하는 비등방성 광전달 소재가 개시된다. 본 발명의 일 실시예에 따른 비등방성 광전달 소재는 광의 파장을 변환시키는 나노 형광체 및 나노 양자점 중 적어도 하나가 몸체 내부에 혼합 분산되어 있는 것으로, 상기 몸체가 섬유상 형태를 가지는 것을 특징으로 한다.
Abstract:
PURPOSE: A material is provided to obtain high conductivity by transferring phonons along the surface of a particle without dispersing the phonons in a polymer resin. CONSTITUTION: A material(100) comprises an elastic particle(130) formed of a polymer resin; and a highly thermal conductive particle(110) which is coupled to the surface of the elastic particle by an integrated high spinning method. The elastic modulus of the elastic particle is 0.01-100 GPa. The thermal conductivity of the highly thermal conductive particle is 1.0-2,000 W/mK. The size of the elastic particle is 1micron-100mm. The particle size of the highly thermal conductive particle is 1nm-1mm. The highly thermal conductive particle is coupled to the surface of the elastic particle.
Abstract:
PURPOSE: A polymer composite for producing insulating material of high voltage direct current cable for transmission is provided to minimize insulation voltage degradation which occurs dielectric breakdown at voltage lower than initially designed dielectric breakdown voltage. CONSTITUTION: A polymer composite for producing insulating material of high voltage direct current cable comprises a graphite nanofiber partially carbonized by 80-0.01 %, or graphite nanoparticles partially carbonized to 80-0.01%. A manufacturing method the polymer composite comprises a step of manufacturing a graphite nanofiber partially carbonized by carbonizing the graphite nano fiber; a step of manufacturing a polymer composite comprising the partially carbonized graphite nanofiber. [Reference numerals] (AA) Embodiment; (BB) Comparative embodiment
Abstract:
The present invention relates to a transparent electronic device having 2D transition metal dichalcogenides with multi-layers, an optoelectronic device, and a transistor device. Preferably, the present invention relates to form a channel layer between transparent layers by forming a multilayer which consisting of at least three layers of a single transition metal dichalcogenide. For this, a transparent electronic device using transition metal dichalcogenides with multi-layers includes electrodes made of a transparent conductive material, and a channel region which is formed between the electrodes by the transition metal dichalcogenides.
Abstract:
PURPOSE: A transparency display panel including a photochromic material layer is provided to allow a coating with photochromic materials on the upper part of a second electrode, thereby omitting a passivation process and redirection process of forming electrode between a light emitting layer and photochromic material layer. CONSTITUTION: A transparent display panel (100) comprises a first electrode, a second electrode (120,140) and a light emitting layer (130). The first electrode and second electrode are laminated on a transparent substrate (110). The light emitting layer is equipped between the first electrode and second electrode. A photochromic material layer (150) is coated on the top of the second electrode and includes photochromic materials.
Abstract:
PURPOSE: A supporting structure for a flexible substrate and a flexible substrate supporting method are provided to easily attach and detach the flexible substrate by using a supporting unit which is divided into a plurality of parts. CONSTITUTION: A support layer(120) is formed on an elastic layer(110). The support layer is formed to be separated into multiple support units(121) as the elastic layer extends and shrinks. The support layer supports a flexible substrate(10). The elastic layer is formed to be extended and shrunk in a transverse direction. The multiple support units are formed to be separated in a transverse direction as the elastic layer extends and shrinks in a transverse direction.