Abstract: The application discloses a light-emitting device including a carrier, a light-emitting element and a connecting structure. The carrier includes a first connecting portion and a first necking portion extended from the first connecting portion. The first connecting portion has a first width, and the first necking portion has a second width. The second width is less than the first width. The light-emitting element includes a first light-emitting layer being able to emit a first light and a first contacting electrode formed under the first light-emitting layer. The first contacting electrode is corresponded to the first connecting portion. The connecting structure includes a first electrical connecting portion and a protecting portion surrounding the first electrical connecting portion. The first electrical connecting portion is electrically connected to the first connecting portion and the first contacting electrode.

Abstract: A light-emitting module includes a common carrier; a plurality of semiconductor devices formed on the common carrier, and each of the plurality of semiconductor devices including three semiconductor dies; a carrier including a connecting surface; a third bonding pad and a fourth bonding pad formed on the connecting surface; and a connecting layer. One of the three semiconductor dies includes a stacking structure; a first bonding pad; and a second bonding pad with a shortest distance less than 150 microns between the first bonding pad. The connecting layer includes a first conductive part including a first conductive material having a first shape; and a blocking part covering the first conductive part and including a second conductive material having a second shape with a diameter in a cross-sectional view. The first shape has a height greater than the diameter.

Abstract: A semiconductor device comprises a semiconductor die, comprising a stacking structure, a first bonding pad with a first bonding surface positioned away from the stacking structure, and a second bonding pad; a carrier comprising a connecting surface; a third bonding pad which comprises a second bonding surface and is arranged on the connecting surface, and a fourth bonding pad arranged on the connecting surface; and a conductive connecting layer comprising a first conducting part, comprising a first outer boundary, and formed between and directly contacting the first bonding pad and the third bonding pad; a second conducting part formed between the second bonding pad and the fourth bonding pad; and a blocking part covering the first conducting part.

Abstract: A light-emitting element having a light-emitting unit, a transparent layer and a wavelength conversion layer formed on the transparent layer. The transparent layer covers the light-emitting unit. The wavelength conversion layer includes a phosphor layer having a phosphor and a stress release layer without the phosphor.

Abstract: This disclosure discloses a light-emitting element having a light-emitting unit, a transparent layer and a wavelength conversion layer formed on the transparent layer. The transparent layer covers the light-emitting unit. The wavelength conversion layer includes a phosphor layer having a phosphor and a stress release layer without the phosphor.

Abstract: The application discloses a light-emitting device including a carrier, a light-emitting element and a connecting structure. The carrier includes a first connecting portion and a first necking portion extended from the first connecting portion. The first connecting portion has a first width, and the first necking portion has a second width. The second width is less than the first width. The light-emitting element includes a first light-emitting layer being able to emit a first light and a first contacting electrode formed under the first light-emitting layer. The first contacting electrode is corresponded to the first connecting portion. The connecting structure includes a first electrical connecting portion and a protecting portion surrounding the first electrical connecting portion. The first electrical connecting portion is electrically connected to the first connecting portion and the first contacting electrode.

Abstract: A light-emitting device includes a light-emitting element having a first electrode and a second electrode, a carrier, a first contact and a second contact. The first contact is arranged on the carrier and is electrically connected to the first electrode. The second contact is arranged on the carrier and is electrically connected to the second electrode. The first contact has a contour similar with that of the first electrode. The second contact has a contour similar with that of the second electrode.

Abstract: A semiconductor device comprises a semiconductor die, comprising a stacking structure, a first bonding pad with a first bonding surface positioned away from the stack structure, and a second bonding pad; a carrier comprising a connecting surface; a third bonding pad which comprises a second bonding surface and is arranged on the connecting surface, and a fourth bonding pad arranged on the connecting surface of the carrier; and a conductive connecting layer comprising a first conductive part, comprising a first outer contour, and formed between and directly contacting the first bonding pad and the third bonding pad; a second conductive part formed between the second bonding pad and the fourth bonding pad; and a blocking part covering the first conductive part to form a covering area, wherein the first bonding surface comprises a first position which is the closest to the carrier within the covering area and a second position which is the farthest from the carrier within the covering area in a cross section vie

Abstract: A semiconductor device comprises a semiconductor die, comprising a stacking structure, a first bonding pad, and a second bonding pad on a top surface of the stacking structure, wherein a shortest distance between the first bonding pad and the second bonding pad is less than 150 ?m; a carrier comprising a connecting surface; a third bonding pad and a fourth bonding pad on the connecting surface of the carrier; and a conductive connecting layer comprising a current conductive area between the first bonding pad and the third bonding pad and between the second bonding pad and the fourth bonding pad.

Abstract: This disclosure discloses a light-emitting element having a light-emitting unit, a transparent layer and a wavelength conversion layer formed on the transparent layer. The transparent layer covers the light-emitting unit.

Abstract: A semiconductor device comprises a semiconductor die, comprising a stacking structure, a first bonding pad, and a second bonding pad on a top surface of the stacking structure, wherein a shortest distance between the first bonding pad and the second bonding pad is less than 150 ?m; a carrier comprising a connecting surface; a third bonding pad and a fourth bonding pad on the connecting surface of the carrier; and a conductive connecting layer comprising a current conductive area between the first bonding pad and the third bonding pad and between the second bonding pad and the fourth bonding pad.

Abstract: A thin-film deposition apparatus comprises a chamber; a carrier in the chamber; a showerhead on the carrier, wherein the showerhead comprises multiple first gas-dispensing holes, multiple second gas-dispensing holes and multiple plasma-generating portions; and a first gas inlet system for providing a first process gas, wherein the first process gas outputted from the multiple first gas-dispensing holes.

Abstract: An LED includes a first intermetallic layer, a first metal thin film layer, an LED chip, a substrate, a second metal thin film layer, and a second intermetallic layer. The first metal thin film layer is located on the first intermetallic layer. The LED chip is located on the first metal thin film layer. The second metal thin film layer is located on the substrate. The second intermetallic layer is located on the second metal thin film layer, and the first intermetallic layer is located on the second intermetallic layer. Materials of the first and the second metal thin film layer are selected from a group consisting of Au, Ag, Cu, and Ni. Materials of the intermetallic layers are selected from a group consisting of a Cu—In—Sn intermetallics, an Ni—In—Sn intermetallics, an Ni—Bi intermetallics, an Au—In intermetallics, an Ag—In intermetallics, an Ag—Sn intermetallics, and an Au—Bi intermetallics.

Abstract: A method for bonding an LED wafer, a method for manufacturing an LED chip, and a bonding structure are provided. The method for bonding an LED wafer includes the following steps. A first metal film is formed on an LED wafer. A second metal film is formed on a substrate. A bonding material layer whose melting point is lower than or equal to about 110° C. is formed on the surface of the first metal film. The LED wafer is placed on the substrate. The bonding material layer is heated at a pre-solid reaction temperature for a pre-solid time to perform a pre-solid reaction. The bonding material layer is heated at a diffusion reaction temperature for a diffusing time to perform a diffusion reaction, wherein the melting points of the first and the second inter-metallic layers after diffusion reaction are higher than about 110° C.

Abstract: An LED includes a first intermetallic layer, a first metal thin film layer, an LED chip, a substrate, a second metal thin film layer, and a second intermetallic layer. The first metal thin film layer is located on the first intermetallic layer. The LED chip is located on the first metal thin film layer. The second metal thin film layer is located on the substrate. The second intermetallic layer is located on the second metal thin film layer, and the first intermetallic layer is located on the second intermetallic layer. Materials of the first and the second metal thin film layer are selected from a group consisting of Au, Ag, Cu, and Ni. Materials of the intermetallic layers are selected from a group consisting of a Cu—In—Sn intermetallics, an Ni—In—Sn intermetallics, an Ni—Bi intermetallics, an Au—In intermetallics, an Ag—In intermetallics, an Ag—Sn intermetallics, and an Au—Bi intermetallics.

Abstract: A die-bonding method is suitable for die-bonding a LED chip having a first metal thin-film layer to a substrate. The method includes forming a second metal thin film layer on a surface of the substrate; forming a die-bonding material layer on the second metal thin film layer; placing the LED chip on the die-bonding material layer with the first metal thin film layer contacting the die-bonding material layer; heating the die-bonding material layer at a liquid -solid reaction temperature for a pre-curing time, so as to form a first intermetallic layer and a second intermetallic layer; and heating the die-bonding material layer at a solid-solid reaction temperature for a curing time for performing a solid-solid reaction. The liquid-solid reaction temperature and the solid-solid reaction temperature are both lower than 110° C., and a melting point of the first and second intermetallic layers after the solid-solid reaction is higher than 200° C.

Abstract: A multi-stack package light emitting diode (LED) includes an LED chip, a first fluorescent powder layer, a first optical bandpass filter layer and a second fluorescent powder layer. The LED chip generates an LED light. The first fluorescent powder layer and the second fluorescent powder layer respectively have a first fluorescent powder and a second fluorescent powder. The first fluorescent powder and the second fluorescent powder are excited by the LED light to respectively generate a first excitation light and a second excitation light. The first optical bandpass filter layer allows the LED light and the first excitation light to pass and reflects the second excitation light. A wavelength of the LED light is shorter than a wavelength of the second excitation light. The wavelength of the second excitation light is shorter than a wavelength of the first excitation light. Therefore, the multi-stack package LED improves a light emission efficiency.

Abstract: A die-bonding method is suitable for die-bonding a LED chip having a first metal thin-film layer to a substrate. The method includes forming a second metal thin film layer on a surface of the substrate; forming a die-bonding material layer on the second metal thin film layer; placing the LED chip on the die-bonding material layer with the first metal thin film layer contacting the die-bonding material layer; heating the die-bonding material layer at a liquid-solid reaction temperature for a pre-curing time, so as to form a first intermetallic layer and a second intermetallic layer; and heating the die-bonding material layer at a solid-solid reaction temperature for a curing time, so as to perform a solid-solid reaction. The liquid-solid reaction temperature and the solid-solid reaction temperature are both lower than 110° C., and a melting point of the first and second intermetallic layers after the solid-solid reaction is higher than 200° C.

Abstract: A tunable light transceiver module for adjusting a photoelectric device is provided. The tunable structure includes a photoelectric device, a stage, and a set of two-dimensional actuators having a first direction actuator and a second direction actuator. The photoelectric device is installed on the stage. The first direction actuation device and the second direction actuation device are coupled to the stage for controlling the movement of the stage along the first direction and the second direction, which are parallel to the stage. The tunable module may comprise an additional vertical actuator for controlling the movement of the stage along the direction perpendicular to the stage, thus realizing the displacement adjustment in three dimensions.

Abstract: An optical splitter with reflection suppression is disclosed. It includes an input waveguide and a plurality of receiving waveguides. The input waveguide has at least one output surface for transferring an incident light to the receiving surfaces of the receiving waveguides. Each of the output surfaces parallels the corresponding receiving surfaces, and an oblique angle is formed between the output surface and the progressing direction of the incident light.