The present invention discloses a transferring method, a manufacturing method, a device and an electronic apparatus of micro-LED. The method for transferring micro-LED comprises: forming micro-LEDs on a laser-transparent original substrate; irradiating the original substrate with laser from the original substrate side to lift-off the micro-LEDs from the original substrate; bring the micro-LEDs into contact with pads preset on a receiving substrate through a contactless action.

A chip arranging method for arranging a plurality of chips on a wafer includes a groove forming step of forming a plurality of intersecting grooves that mark off each of chip placement regions on the front surface side of the wafer, a liquid supplying step of supplying a liquid to the chip placement regions, a chip placing step of placing the chips on the liquid to position the chips in the chip placement regions by the surface tension of the liquid after carrying out the liquid supplying step, and a liquid removing step of removing the liquid to arrange the plurality of chips on the wafer after carrying out the chip placing step.

The present disclosure provides a method of transferring an electronic element using a stamping and magnetic field alignment technology and an electronic device including an electronic element transferred using the method. In the present disclosure, a polymer may be simultaneously coated on a plurality of electronic elements using the stamping process, and the polymer may be actively coated on the electronic elements without restrictions on process parameters such as size and spacing of the electronic elements. Moreover, the self-aligned ferromagnetic particles have an anisotropic current flow through which current flows only in the aligned direction. Therefore, the current may flow only vertically between the electronic element and the electrode, and there is no electrical short circuit between a peripheral LED element and the electrode.

A method includes forming a first tacking layer on a first connection partner, arranging a first layer on the first tacking layer, forming a second tacking layer on the first layer, arranging a second connection partner on the second tacking layer, heating the tacking layers and first layer, and pressing the first connection partner towards the second connection partner, with the first layer arranged between the connection partners, such that a permanent mechanical connection is formed between the connection partners. Either the tacking layers each include a second material evenly distributed within a first material, the second material being configured to act as or to release a reducing agent, or the tacking layers each include a mixture of at least a third material and a fourth material, the materials in the mixture chemically reacting with each other under the influence of heat such that a reducing agent is formed.

A semiconductor arrangement includes a lower semiconductor chip, an upper semiconductor chip arranged over an upper main side of the lower semiconductor chip, a metallization layer arranged on the upper main side of the lower semiconductor chip, and a bonding material which fastens the upper semiconductor chip on the lower semiconductor chip. The metallization layer includes a structure with increased roughness in comparison with the rest of the metallization layer, the structure being arranged along a contour of the upper semiconductor chip.

The present disclosure relates to a full-color light-emitting diode (LED) display, and more particularly, to a full-color LED display using an ultra-thin LED element and a manufacturing method thereof.

The present disclosure provides a method of transferring an electronic element using a stamping and magnetic field alignment technology and an electronic device including an electronic element transferred using the method. In the present disclosure, a polymer may be simultaneously coated on a plurality of electronic elements using the stamping process, and the polymer may be actively coated on the electronic elements without restrictions on process parameters such as size and spacing of the electronic elements. Moreover, the self-aligned ferromagnetic particles have an anisotropic current flow through which current flows only in the aligned direction. Therefore, the current may flow only vertically between the electronic element and the electrode, and there is no electrical short circuit between a peripheral LED element and the electrode.

An apparatus includes a first component layer. The component layer includes a first semiconductor device. The apparatus further includes a first hydrophilic layer and a first hydrophobic layer. The first hydrophobic layer is positioned between the first component layer and the first hydrophilic layer. The apparatus further includes a first contact extending through the first hydrophobic layer and the first hydrophilic layer.

A method for manufacturing a display device can include growing a plurality of light emitting (LEDs) on a growing substrate; forming a member having a thermal flow characteristic on at least one side surface of each of the plurality of LEDs; separating each of the plurality of LEDs from the growing substrate; forming a plurality of assembly grooves in a wiring substrate for defining pixel regions; assembling the plurality of LEDs at locations respectively corresponding to the plurality of assembly grooves; and applying heat to the wiring substrate to perform a reflow process for adjusting a position of at least one of the plurality of LEDs.

A display device includes a first substrate that includes a first electrode, a second substrate disposed under the first substrate and that includes, a second electrode that overlaps the first electrode, and an anisotropic conductive film disposed between the first substrate and the second substrate. The anisotropic conductive film includes an insulating resin layer and a plurality of conductive particles in the insulating resin layer. The conductive particles include first conductive particles that overlap the first electrode and the second electrode, and second conductive particles other than the first conductive particles. Each of the first conductive particles and the second conductive particles includes a first flat surface, a second flat surface that faces the first flat surface, and a curved surface rounded between the first flat surface and the second flat surface.