Abstract: A method for indenting coloring-areas of a colored 3D object includes: importing a 3D object; performing a slicing process on the 3D object for generating multiple object printing data-records and multiple color printing data-records of multiple printing layers; performing an indenting process on a color printing data-record of a lowest coloring-required printing layer for generating an indented color printing data-record; storing the multiple object printing data-records, the multiple color printing data-records, and the indented color printing data-record.

Abstract: An inkjet method adapting to a three-dimensional printing device is provided. The inkjet method includes following steps: judging whether a first reference pixel value of a first reference pixel in a first reference image is greater than or equal to a preset threshold value to determine a first pixel value of a first pixel in a first inkjet image; generating a weight value corresponding to a second reference pixel according to number of the second reference pixel adjacent to the first reference pixel in the first reference image and a second reference image; and adjusting a second reference pixel value of the second reference pixel in the first reference image and the second reference image according to the first reference pixel value, the first pixel value, and the weight value. In addition, the above three-dimensional printing device is also provided.

Abstract: A 3D printing method using strengthened auxiliary wall is provided. The method is to control a 3D printer to retrieve multiple layers of object print data corresponding to a 3D object, and multiple layers of wall print data and raft print data, print multiple layers of raft slice physical models on a print platform layer by layer according to the raft print data, print multiple layers of wall slice physical models on the printed raft slice physical models layer by layer according to the wall print data, and print multiple layers of 3D slice physical models layer by layer according to the object print data during printing the raft slice physical models and the wall slice physical models. It can effectively prevent the auxiliary wall form collapsing and failure of printing a whole 3D physical model via making a raft structure be arranged under the auxiliary wall.

Abstract: The present disclosure provides a method for forming a semiconductor structure. In accordance with some embodiments, the method includes providing a substrate and a conductive feature formed over the substrate; forming a low-k dielectric layer over the conductive feature; forming a contact trench aligned with the conductive feature; and selectively growing a sealing layer which is a monolayer formed on sidewalls of the contact trench.

Abstract: A three-dimensional printing method for a three-dimensional printer is provided. The three-dimensional printer includes a model printing head, a color printing head, and a platform. The model printing head prints a forming layer on an X-Y plane of the platform. The model printing head and the color printing head are arranged along an X-axis and co-constructed. The three-dimensional printing method includes: providing information of the forming layer and a coloring zone thereof; driving the model printing head by a processor to print the forming layer and at least one material barrier outside the forming layer; and after printing the forming layer and the material barrier, driving the color printing head by the processor to color the coloring zone along a Y-axis, such that the material barrier is located on a moving path of the model printing head during the coloring.

Abstract: A three-dimensional printing apparatus including a fusion nozzle and a control device is provided. The fusion nozzle is configured to heat a molding material at a heating temperature. The control device is coupled to the fusion nozzle. The control device is configured to control the fusion nozzle to perform a printing operation according to a slicing image. The control device determines the heating temperature of the fusion nozzle according to slicing contour information of a slicing object in the slicing image. In addition, a three-dimensional printing method is also provided.

Abstract: A light-emitting device includes: a rectangular shape with a first side, a second side opposite to the first side, and a third side connecting the first side and the second side; a light-emitting stack, comprising a lower semiconductor layer, an upper semiconductor layer, and an active layer between the lower semiconductor layer and the upper semiconductor layer; a first electrode formed on the lower semiconductor layer, comprising a first electrode pad and a first extension electrode; a second electrode formed on the upper semiconductor layer, comprising a second electrode pad and a second extension electrode; and a first current blocking layer formed between the lower semiconductor layer and the first electrode pad, wherein the first current blocking layer comprises a top surface and side surfaces; wherein the first electrode pad covers the top surface and the side surfaces of the first current blocking layer and contacts the lower semiconductor layer.

Abstract: A color three-dimensional printing method and a three-dimensional printing equipment are provided. A slicing processing is performed on a 3D model to obtain a printing path file and a plurality of inkjet images. A first layer controlling data in the printing path file is read, wherein the first layer controlling data records a plurality of printing position points and a plurality of inkjet position points. Movement of a printing head is controlled according to the printing position points, and the printing head is controlled to extrude a forming material, to establish a first layer object. A first inkjet image among the inkjet images is read. Movement of an inkjet head on a plane is controlled according to the inkjet position points, and the inkjet head is controlled to spray the ink on the first layer object according to the first inkjet image.

Abstract: A color three-dimensional printing method and three-dimensional printing equipment are provided, which are adapted to present a color pattern on a three-dimensional object. The method includes following steps. A color image including the color pattern is obtained, and the color image includes a plurality of pixels. An inkjet depth of each of the pixels is determined based on a color feature of each of the pixels. A three-dimensional model of the three-dimensional object is sliced to generate layer information of a plurality of layer objects. A plurality of inkjet pictures corresponding to the layer objects are obtained based on the inkjet depths of the respective pixels.

Abstract: A light-emitting device is provided. The light-emitting device comprises a substrate; a semiconductor stack on the substrate comprising a first region and a second region; a first trench extending from the semiconductor stack to the substrate to expose a surface of the substrate and separating the first region from the second region; and a first electrode comprising a first pad on the first region and a first extending electrode connecting to the first pad, wherein the first extending electrode is across the first trench.

Abstract: A light-emitting device includes: a rectangular shape with a 1st side, a 2nd side opposite to the 1st side, and a 3rd side connecting the 1st and the 2nd sides; a first electrode pad formed adjacent to the 3rd side; a second electrode pad formed adjacent to the 2nd side; a first extension electrode, extending from the first electrode pad in a direction away from the 3rd side and bended toward the 2nd side; and a second extension electrode, including a first and a second branches respectively extending from the second electrode pad; wherein a distance between the first electrode pad and the 3rd side is smaller than a distance between the second electrode pad and the 3rd side; wherein an end portion of the first branch includes a first arc bending to the 3rd side and a minimum distance between the first branch and the 1st side is smaller than a minimum distance between the second branch and the 1st side.

Abstract: A method embodiment for forming a semiconductor device includes providing a dielectric layer having a damaged surface and repairing the damaged surface of the dielectric layer. Repairing the damaged surface includes exposing the damaged surface of the dielectric layer to a precursor chemical, activating the precursor chemical using light energy, and filtering out a spectrum of the light energy while activating the precursor chemical.

Abstract: A printing method for shielding component adopted to print a shielding component (2) of a 3D model (20) having multiple printing layers (11) is disclosed. The method first obtains all candidate points of first layer of the shielding component (2) and chooses one of the candidate points as a start point (211) of the first layer according to a default rule, and prints the first layer from the chosen start point (211). Next, the method obtains all candidate points of next layer of the shielding component (2) and chooses one of the candidate points of the next layer which is closest to the start point (211) of last layer to be printed as a start point of the next layer, and prints the next layer from the chosen start point.

Abstract: A method for compensating coloring range of colored 3D object is disclosed. The method includes following steps: importing a 3D object; performing an object slicing process to the 3D object for generating multiple object printing-route information for multiple printing layers; performing an image slicing process to the 3D object for generating multiple color printing-route information for the multiple printing layers; performing an extension process to the color printing-route information for generating updated color printing-route information, the updated color printing-route information may cover extension blocks respectively generated from each sliced object after the sliced object is printed.

Abstract: A printing method for color compensation adopted by a 3D printer (1) having a 3D nozzle (121) and a 2D nozzle (122) is disclosed. The printing method includes following steps of: controlling the 3D nozzle (121) to print a slicing object (2) of the 3D object upon a printing platform (11) according to a route file; controlling the 2D nozzle (122) to perform coloring on the printed slicing object (2) according to an image file; controlling the 2D nozzle (122) and the printing platform (1) to rotate relatively for creating an angular transposition between the 2D nozzle (122) and the printing platform (1) after the slicing object (2) is colored completely; and, controlling the 2D nozzle (122) to again perform coloring on the colored slicing object (2) after the 2D nozzle (2) and the printing platform (11) rotated relatively.

Abstract: A method for deleting internal color information of 3D object (2) is disclosed and includes following steps: performing an object slicing process to an input 3D object (2) for obtaining data of at least two printing layers (3) of the 3D object (2); performing a comparing action to two adjacent printing layers according to the data of the two adjacent printing layers; determining an overlapped area (30) of a lower printing layer (31) and an adjacent upper printing layer (32) according to a comparing result of the comparing action; deleting color information in the overlapped area (30) from the data of the lower printing layer (31); and updating the data of the lower printing layer (31) according to the deleted color information.

Abstract: An electrostatic detecting system and an electrostatic detecting method for detecting the static electricity generated at an active surface of a substrate are provided. The electrostatic detecting system includes a sensing apparatus and a signal processing apparatus. The sensing apparatus is disposed at least adjacent to a back surface opposite to the active surface of the substrate, for measuring the static electricity generated at the active surface and generating an initial electric signal. The signal processing apparatus is electrically connected to the sensing apparatus, for receiving the initial electric signal and correcting the initial electric signal based on a voltage compensation value to obtain a final electric signal.

Abstract: A chip package includes a chip, a dam layer, a carrier substrate and a light shielding passivation layer. The chip has a first surface and a second surface opposite to the first surface, and a side surface is disposed between the first surface and the second surface. The dam layer is disposed on the first surface, and the carrier substrate is disposed on the dam layer. The light shielding passivation layer is disposed under the second surface and extended into the carrier substrate to cover the side surface of the chip.

Abstract: Methods for depositing titanium oxide films by atomic layer deposition are disclosed. Titanium oxide films may include a titanium nitride cap, an oxygen rich titanium nitride cap or a mixed oxide nitride layer. Also described are methods for self-aligned double patterning including titanium oxide spacer films.