Abstract: Methods of dicing semiconductor wafers, each wafer having a plurality of integrated circuits, are described. A method includes forming a mask above the semiconductor wafer, the mask including a layer covering and protecting the integrated circuits. The mask and a portion of the semiconductor wafer are patterned with a laser scribing process to provide a patterned mask and to form trenches partially into but not through the semiconductor wafer between the integrated circuits. Each of the trenches has a width. The semiconductor wafer is plasma etched through the trenches to form corresponding trench extensions and to singulate the integrated circuits. Each of the corresponding trench extensions has the width.

Abstract: Methods for processing a semiconductor workpiece can include providing a semiconductor workpiece that includes one or more kerf regions; forming one or more trenches in the workpiece by removing material from the one or more kerf regions from a first side of the workpiece; mounting the workpiece with the first side to a carrier; thinning the workpiece from a second side of the workpiece; and forming a metallization layer over the second side of the workpiece.

Abstract: A method of making an inkjet print head may include forming, by sawing with a rotary saw blade, first discontinuous slotted recesses in a first surface of a wafer. The first discontinuous slotted recesses may be arranged in parallel, spaced apart relation. The method may further include forming, by sawing with the rotary saw blade, second discontinuous slotted recesses in a second surface of the wafer aligned and coupled in communication with the first continuous slotted recesses to define through-wafer channels. In another embodiment, the first and second plurality of discontinuous recesses may be formed by respective first and second rotary saw blades.

Abstract: A method for manufacturing a semiconductor element is provided. The method includes providing a semiconductor wafer including a substrate and a semiconductor structure on the substrate, forming a cleavage starting portion in the semiconductor wafer, and dividing the semiconductor wafer into a plurality of semiconductor elements by transferring a pressing member on the semiconductor wafer in a state where the pressing member is pressed against the semiconductor wafer to separate the semiconductor wafer at the cleavage starting portion. The pressing member includes a tip portion to be pressed on the semiconductor wafer, and the tip portion has a spherical surface.

Abstract: A semiconductor device includes a substrate and a conductive layer. The substrate has an upper surface that is a substantially rectangular shape having a pair of two sides extending in a first direction and a pair of two sides extending in a second direction. The conductive layer is provided on the substrate and extending along a periphery of the substrate. The conductive layer extends and zigzags toward the first direction.

Abstract: A light emitting device having improved light extraction is provided. The light emitting device can be formed by epitaxially growing a light emitting structure on a surface of a substrate. The substrate can be scribed to form a set of angled side surfaces on the substrate. For each angled side surface in the set of angled side surfaces, a surface tangent vector to at least a portion of each angled side surface in the set of angled side surfaces forms an angle between approximately ten and approximately eighty degrees with a negative of a normal vector of the surface of the substrate. The substrate can be cleaned to clean debris from the angled side surfaces.

Abstract: A method includes forming a molding compound molding a lower portion of an electrical connector of a wafer therein. The molding compound is at a front surface of the wafer. The molding compound covers a center region of the wafer, and leaves an edge ring of the wafer not covered. An opening is formed to extend from the front surface of the wafer into the wafer, wherein the opening is in the edge ring of the wafer. A backside grinding is performed on the wafer until the opening is revealed through a back surface of the wafer. The method further includes determining a position of a scribe line of the wafer using the opening as an alignment mark, and sawing the wafer from a backside of the wafer by sawing through the scribe line.

Abstract: Disclosed is a method for separating a substrate (1) along a separation pattern (4), in which method a substrate (1) is provided and an auxiliary layer (3) is applied to the substrate, said layer covering the substrate at least along the separation pattern. The substrate comprising the auxiliary layer is irradiated, such that the material of the auxiliary layer penetrates the substrate along the separation pattern in the form of an impurity. The substrate is broken along the separation pattern. A semiconductor chip (15) is also disclosed.

Abstract: Packaged semiconductor devices and methods of packaging semiconductor devices are disclosed. In some embodiments, a packaged semiconductor device includes an integrated circuit die, a first molding material disposed around the integrated circuit die, and a through-via disposed within the first molding material. A first side of a redistribution layer (RDL) is coupled to the integrated circuit die, the through-via, and the first molding material. A second molding material is over a second side of the RDL, the second side of the RDL being opposite the first side of the RDL. The packaged semiconductor device includes an antenna over the second molding material.

Abstract: Methods and apparatuses are provided where a parting agent is applied to at least one portion of a substrate. The at least one portion of the substrate is removed from a carrier.

Abstract: A semiconductor device includes a semiconductor die. A dielectric material surrounds the semiconductor die to form an integrated semiconductor package. There is a contact coupling to the integrated semiconductor package and configured as a ground terminal for the semiconductor package. The semiconductor device further has an EMI (Electromagnetic Interference) shield substantially enclosing the integrated semiconductor package, wherein the EMI shield is coupled with the contact through a path disposed in the integrated semiconductor package.

Abstract: According to the present invention, there is provided a semiconductor wafer protective film including a substrate layer (A) and an adhesive layer (C) formed on the substrate layer (A), in which the substrate layer (A) includes polymer, and a solubility parameter of the polymer determined by a Van Krevelen method is equal to or greater than 9.

Abstract: A system for interconnecting at least two die each die having a plurality of conducting layers and dielectric layers disposed upon a substrate which may include active and passive elements. In one embodiment there is at least one interconnect coupling at least one conducting layer on a side of one die to at least one conducting layer on a side of the other die. Another interconnect embodiment is a slug having conducting and dielectric layers disposed between two or more die to interconnect between the die. Other interconnect techniques include direct coupling such as rod, ball, dual balls, bar, cylinder, bump, slug, and carbon nanotube, as well as indirect coupling such as inductive coupling, capacitive coupling, and wireless communications. The die may have features to facilitate placement of the interconnects such as dogleg cuts, grooves, notches, enlarged contact pads, tapered side edges and stepped vias.

Abstract: A method for producing a lighting module is provided. The method includes providing a light source substrate populated with at least one semiconductor light source, laterally surrounding the at least one semiconductor light source by a wall, applying at least one prefabricated diffuser element to at least one semiconductor light source, introducing potting compound into the space surrounded by the wall up to a height at which both the at least one semiconductor light source, and potting at least part of the at least one diffuser element.

Abstract: An embodiment includes a substrate treating apparatus comprising: a tape supply member configured to supply a tape to be attached to a substrate; a tape collection member configured to collect a surplus tape that remains after the tape is attached to the substrate; a support member disposed between the tape supply member and the tape collection member and configured to support the substrate while the tape is attached to the substrate; and a temperature adjustment member configured to adjust a temperature of the tape that is supplied from the tape supply member to the support member.

Abstract: Disclosed herein is a wafer processing method including the steps of attaching a dicing tape to the back side of a wafer, the dicing tape being composed of a base tape, a DAF, and an adhesive layer for uniting the base tape and the DAF, imaging the wafer through the dicing tape to obtain an image of the wafer, detecting the positions of poor adhesion of the DAF from the image, storing the positions of poor adhesion detected above, dividing the wafer and the DAF into individual chips each having the DAF, curing the adhesive layer of the dicing tape by the application of ultraviolet light, selectively separating the chips with the DAF well adhered, at the boundary between the adhesive layer and the DAF according to the positions of poor adhesion stored above, and then picking up the chips with the DAF well adhered.

Abstract: Embodiments transfer thin layers of material utilized in electronic devices (e.g., GaN for optoelectronic devices), from a donor to a handle substrate. Certain embodiments employ bond-and-release system(s) where release occurs along a cleave plane formed by implantation of particles into the donor. Some embodiments may rely upon release by converting components from solid to liquid under carefully controlled thermal conditions (e.g., solder-based materials and/or thermal decomposition of Indium-containing materials). Some embodiments utilize laser-induced film release processes using epitaxially grown or implanted regions as an optically absorptive region. A single bond-and-release sequence may involve processing an exposed N-face of GaN material. Multiple bond-and-release sequences (involving processing an exposed Ga-face of GaN material) may be employed in series, for example utilizing a temporary handle substrate as an intermediary.

Abstract: A method for thinning samples including the steps of: a) providing at least one sample having a front and a rear face, b) providing a frame substrate having a first face and a second face opposite the first, including a through-opening which opens into the first and second face, which is configured to receive the sample, c) positioning the sample so it is disposed in the through-opening, the front face being oriented to the same side as the first face, and d) thinning the frame substrate and the sample simultaneously from the first face and the front face, respectively, so that at the end of thinning, the faces extend substantially in the same plane, the thinning being carried out using a grinder, the frame substrate and the sample being disposed on a rotary disk held in place by aspiration, the flanks of the sample remaining free during the thinning.

Abstract: The instant disclosure relates to a method for making solid electrolytic capacitor package structure with improved conductive terminals. The first step is to provide at least one conductive terminal having an electrical contact portion and a lead-out portion. The next step is to remove a portion of mantle layer from the surface of the core layer of at least one conductive terminal by a dry-type process. The next step is to sequentially stack together a plurality of stacked-type capacitors to form a capacitor unit and then electrically connect the capacitor unit to at least one conductive terminal. The next step is to form a package body to encapsulate the capacitor unit and the electrical contact portion of at least one conductive terminal. The last step is to bend the lead-out portion of at least one conductive terminal to an axis that extends along the surface of the package body.

Abstract: A semiconductor device includes a substrate layer, a redistribution layer (RDL) disposed over the substrate layer, a conductive bump disposed over the RDL, and a molding disposed over the RDL and surrounding the conductive bump, wherein the molding includes a protruded portion laterally protruded from a sidewall of the substrate layer and away from the conductive bump.

Abstract: After forming a first trench extending through a top semiconductor layer and a buried insulator layer and into a handle substrate of a semiconductor-on-insulator (SOI) substrate, a dielectric waveguide material stack including a lower dielectric cladding layer, a core layer and an upper dielectric cladding layer is formed within the first trench. Next, at least one lateral bipolar junction transistor (BJT), which can be a PNP BJT, an NPN BJT or a pair of complementary PNP BJT and NPN BJT, is formed in a remaining portion of the top semiconductor layer. After forming a second trench extending through the dielectric waveguide material stack to re-expose a portion of a bottom surface of the first trench, a laser diode is formed in the second trench.

Abstract: A semiconductor die includes a semiconductor body, an insulating layer, a conductive circuit layer and at least one conductive bump. The semiconductor body has a first surface, a second surface and a side surface extending between the first surface and the second surface. The insulating layer is disposed on the first surface and the side surface of the semiconductor body. The insulating layer includes a first insulating layer over the semiconductor body and a second insulating layer over the first insulating later. The insulating layer includes a step structure. The conductive circuit layer is electrically connected to the first surface of the semiconductor body, the conductive circuit layer includes at least one pad, and the conductive bump is electrically connected to the pad.

Abstract: A method for manufacturing a semiconductor element includes providing a wafer having a sapphire substrate and a semiconductor stacked body disposed on the sapphire substrate, performing a first scanning of a portion of the sapphire substrate in which a laser beam is irradiated into an interior of the sapphire substrate, performing a second scanning of the portion of the sapphire substrate in which a laser beam is irradiated into the interior of the sapphire substrate, the second scanning occurring after the first scanning and before a void is produced in the interior of the sapphire substrate irradiated with the laser beam in the first scanning, and separating the wafer into a plurality of semiconductor elements.

Abstract: A method of manufacturing a surface mount device includes forming a plaque from a material, forming a plurality of conductive protrusions on a top surface and a bottom surface of the plaque, and applying a liquid encapsulant over at least a portion of the top surface and at least a portion of the bottom surface of the plaque. The liquid encapsulant is cured and when cured encapsulant has an oxygen permeability of less than about 0.4 cm3·mm/m2·atm·day. The assembly is cut to provide a plurality of components. After cutting, the top surface of each component includes at least one conductive protrusion, the bottom surface of each component includes at least one conductive protrusion, the top surface and the bottom surface of each component include the cured encapsulant, and a core of each component includes the material.

Abstract: According to an embodiment, a method for manufacturing a semiconductor device includes: selectively forming a plurality of mask layers on a first surface of a semiconductor substrate, and the semiconductor substrate having the first surface and a second surface; dividing the semiconductor substrate by forming a gap piercing from the first surface to the second surface of the semiconductor substrate, the gap being formed by dry-etching the first surface of the semiconductor substrate exposed between the plurality of mask layers, and a width of the gap on the second surface side being larger than a width of the gap on the first surface side; and forming a first electrode under a reduced-pressure atmosphere on the first surface of the semiconductor substrate after the semiconductor substrate being divided.

Abstract: Provided are a method of forming an electromagnetic interference (EMI) shielding layer of a ball grid array (BGA) semiconductor package, and a base tape used in the method, and more particularly, a method of forming a shielding layer for blocking EMI, on an upper surface and lateral surfaces of a BGA semiconductor package having a lower surface, on which a plurality of solder balls are formed, and a base tape used in the method. According to the method of forming an EMI shielding layer of a BGA semiconductor package, the EMI shielding layer may be formed on the BGA semiconductor package quickly, easily, and effectively by using the base tape, thereby not only improving process productivity but also remarkably reducing the manufacturing costs.

Abstract: A dividing method for a disk-shaped workpiece having a plurality of first division lines and a plurality of second division lines intersecting the first division lines. The workpiece is cut along the first and second division lines by using a cutting blade in a down cut manner as supplying a cutting fluid to the cutting blade, wherein the workpiece is fully cut in a thickness direction thereof to obtain a plurality of chips. The dividing method includes a first cutting step of cutting the workpiece along the first division lines and a second cutting step of cutting the workpiece along the second division lines. In at least the second cutting step, the outer circumference of the workpiece at the cut end of each second division line is not cut to form an uncut region, thereby suppressing the formation of waste chips.

Abstract: Methods for dicing a wafer is presented. The method includes providing a wafer having first and second major surfaces. The wafer is prepared with a plurality of dies on main device regions and are spaced apart from each other by dicing channels on the first major surface of the wafer. A film is provided over first or second major surface of the wafer. The film covers at least areas corresponding to the main device regions. The method also includes using the film as an etch mask and plasma etching the wafer through exposed semiconductor material of the wafer to form gaps to separate the plurality of dies on the wafer into a plurality of individual dies.

Abstract: A semiconductor device includes a device region including a compound semiconductor material and a non-device region at least partially surrounding the device region. The semiconductor device further includes a dielectric material in the non-device region and at least one electrode in the device region. The semiconductor device further includes at least one pad electrically coupled to the at least one electrode, wherein the at least one pad is arranged on the dielectric material in the non-device region.

Abstract: Vertical high power LEDs are the technological choice for the application of general lighting due to their advantages of high efficiency and capability of handling high power. However, the technologies of vertical LED fabrication reported so far involve the wafer-level metal substrate substitution which may cause large stress due to the mismatch between metal substrate and LED layer. Moreover, the metal substrate has to be diced to separate LED dies which may cause metal contamination and thus increase the leakage current. These factors will lower the yield of LED production and increase the cost as well. The present invention is to disclose a novel method for the fabrication of GaN vertical high power LEDs and/or a novel method for the fabrication of GaN vertical high power LEDs which is compatible to mass production conditions. The novelty of the invention is that the island metal plating is conducted with the help of pattern formation techniques.

Abstract: A wafer processing method including a modified layer forming step of applying a laser beam having a transmission wavelength to the wafer along each division line to thereby form a modified layer inside the wafer along each division line, and a back grinding step of grinding the back side of the wafer to reduce the thickness of the wafer to a predetermined thickness and also divide the wafer along each division line where the modified layer is formed as a break start point, thereby obtaining individual device chips. Prior to performing the back grinding step, the method further includes a protective tape attaching step of attaching a protective tape to the front side of the wafer, the protective tape having an adhesive layer curable by the application of ultraviolet light, and an adhesive layer curing step of applying ultraviolet light to the protective tape to thereby cure the adhesive layer.

Abstract: Methods are provided for processing a substrate in single substrate tool. In one embodiment, the method includes providing the substrate in the single substrate tool, applying a first processing fluid at a first temperature greater than 100° C. to a lower surface of the substrate to heat the substrate to approximately the first temperature, and applying a second processing fluid at a second temperature greater than 100° C. to an upper surface of the substrate.

Abstract: A semiconductor piece manufacturing method includes: a process of forming a fine groove on a front surface side including a first groove portion having a width that is gradually narrowed from a front surface of a semiconductor substrate W toward a rear surface thereof; a process of attaching a dicing tape having an adhesive layer on the front surface after the fine groove on the front surface side is formed; a process of forming a groove on a rear surface side having a width greater than the width of the fine groove on the front surface side along the fine groove on the front surface side from a rear surface side of the substrate by a rotating dicing blade; and a process of separating the dicing tape from the front surface after the groove on the rear surface side is formed.

Abstract: After forming a first trench extending through a top semiconductor layer and a buried insulator layer and into a handle substrate of a semiconductor-on-insulator (SOI) substrate, a dielectric waveguide material stack including a lower dielectric cladding layer, a core layer and an upper dielectric cladding layer is formed within the first trench. Next, at least one lateral bipolar junction transistor (BJT), which can be a PNP BJT, an NPN BJT or a pair of complementary PNP BJT and NPN BJT, is formed in a remaining portion of the top semiconductor layer. After forming a second trench extending through the dielectric waveguide material stack to re-expose a portion of a bottom surface of the first trench, a laser diode is formed in the second trench.

Abstract: In accordance with an embodiment of the present invention, a semiconductor package includes a semiconductor chip and a bump. The semiconductor chip has a contact pad on a major surface. The bump is disposed on the contact pad of the semiconductor chip. A solder layer is disposed on sidewalls of the bump.

Abstract: A device wafer processing method includes, a groove forming step in which grooves with a predetermined depth are formed in the front side of a device wafer; a plate attaching step in which a plate is attached to the front side of the wafer through an adhesive; a grinding step in which the wafer is held by a holding table through the plate so as to expose the back side of the wafer, and the back side is ground to expose the grooves at the back side of the wafer, thereby dividing the wafer to form a plurality of chips. The method further includes: a film attaching step in which a film is attached to the back side of the wafer; and a dicing step in which the film is diced along division lines from the side of the back side of the wafer.

Abstract: A wafer has a substrate, a functional layer and division lines. The wafer is held on a chuck table with a protective member attached to the front side of the functional layer in contact with the chuck table. The height of the back side of the wafer is detected in a Z direction along each division line while moving the chuck table in an X direction. An X coordinate is recorded for each division line, as well as a corresponding Z coordinate. A cutting blade is positioned on the back side of the wafer and moved in the Z direction according to the recorded X and Z coordinates while moving the chuck table in the X direction to thereby form a cut groove having a depth not reaching the functional layer, with a part of the substrate left between the bottom of the cut groove and the functional layer.

Abstract: In a wafer processing tape, circular or tongue-shaped notched parts facing the center of an adhesive layer, as seen in a plan view, are formed so as to correspond to a pasting region to a wafer ring to a depth that reaches a release substrate from the side of a base material film. Due to the formation of the notched parts, when a peeling force acts on the wafer processing tape, portions of a tacky material layer and the base material film which are more outward than the notched parts are peeled off first, and a portion that is more inward than the notched parts remains on the wafer ring in a protruding state. Accordingly, a peeling strength between the wafer processing tape and the wafer ring can be increased and the wafer processing tape can be suppressed from being peeled off from the wafer ring during processes.

Abstract: In one embodiment, a method of forming a semiconductor device comprises forming a groove on and/or over a first side of a substrate. A dicing layer is formed from a second side of the substrate using a laser process. The second side is opposite the first side. The dicing layer is disposed under the groove within the substrate. The substrate is singulated through the dicing layer.

Abstract: A wafer includes a plurality of chips, each of the chips being spaced from each other by kerf-line regions including a reduced width.

Abstract: A method for manufacturing semiconductor devices is disclosed. In one embodiment a semiconductor substrate having a first surface, a second surface opposite to the first surface and a plurality of semiconductor components is provided. The semiconductor substrate has a device thickness. At least one metallization layer is formed on the second surface of the semiconductor substrate. The metallization layer has a thickness which is greater than the device thickness.

Abstract: A method for manufacturing a semiconductor device includes: preparing a semiconductor wafer including a plurality of semiconductor chips arranged in the shape of a matrix, the semiconductor wafer having a first bump electrode formed on one face thereof; forming a depressed portion on a first face of the semiconductor wafer, the depressed portion partitioning the semiconductor wafer into respective semiconductor chips; placing the first face of the semiconductor wafer onto a support tape; and cutting the semiconductor wafer along the depressed portion from a second face opposite to the first face of the semiconductor wafer by the use of a dicing blade having a width smaller than the width of the depressed portion to thereby divide the semiconductor wafer into a plurality of semiconductor chips.

Abstract: To provide a semiconductor device having improved reliability. A method of manufacturing a semiconductor device according to one embodiment includes a step of cutting, in a dicing region arranged between two chip regions adjacent to each other, a wafer along an extending direction of the dicing region. The dicing region has therein a plurality of metal patterns in a plurality of columns. In the step of cutting the wafer, one or more of the columns of metal patterns formed in a plurality of columns are removed, and the metal patterns of the column(s) different from the above-mentioned one or more of the columns are not removed.

Abstract: Methods of dicing semiconductor wafers, each wafer having a plurality of integrated circuits, are described. In an example, a method of dicing a semiconductor wafer having a plurality of integrated circuits involves forming a mask above the semiconductor wafer, the mask including a layer covering and protecting the integrated circuits. The mask is patterned with a laser scribing process to provide a patterned mask with gaps, exposing regions of the semiconductor wafer between the integrated circuits. Subsequent to patterning the mask, the exposed regions of the semiconductor wafer are cleaned with an anisotropic plasma process non-reactive to the exposed regions of the semiconductor wafer. Subsequent to cleaning the exposed regions of the semiconductor wafer, the semiconductor wafer is plasma etched through the gaps in the patterned mask to singulate the integrated circuits.

Abstract: A transfer layer includes a transparent substrate. A buffer layer is formed on the transparent substrate that comprises PbO, GaN, PbTiO3, La0.5Sr0.5CoO3 (LSCO), or LaxPb1-xCoO3 (LPCO) so that separation between the buffer layer and the transparent substrate occurs at substantially high temperatures.

Abstract: A method of fabricating a semiconductor device is disclosed. A photosensitive material is coated over the device. A plurality of masks for a chip layout are obtained. The plurality of masks are exposed to encompass a chip area of the device using at least one reticle repeatedly. The at least one reticle is of a set of reticles. The chip area has a resultant dimension greater than a dimension of the at least one reticle. A developer is used to remove soluble portions of the photosensitive material forming a resist pattern in the chip area.

Abstract: A method of manufacturing a semiconductor device includes the steps of preparing a semiconductor wafer having a thick portion in an outer circumferential end portion and a thin portion in a central portion, attaching a support material to one surface of the semiconductor wafer, dividing the semiconductor wafer into the thick portion and the thin portion, and cutting the thin portion, after the division, while supporting the thin portion by the support material.

Abstract: In one embodiment, methods for making semiconductor devices are disclosed.

Abstract: Approaches for patterning semiconductor or other wafers and dies are described. For example, a method of patterning features within a substrate involves forming a mask layer above a surface of a semiconductor or glass substrate. The method also involves laser ablating the mask layer to provide a pattern of openings through the mask layer. The method also involves plasma etching portions of the semiconductor or glass substrate through the pattern of openings to provide a plurality of trenches in the semiconductor or glass substrate. The plurality of trenches has a pattern corresponding to the pattern of openings and comprising a pattern of through-substrate-via openings or redistribution layer (RDL) openings. The method also involves, subsequent to the plasma etching, removing the mask layer.

Abstract: Examples of methods and systems for laser processing of materials are disclosed. Methods and systems for singulation of a wafer comprising a coated substrate can utilize a laser outputting light that has a wavelength that is transparent to the wafer substrate but which may not be transparent to the coating layer(s). Using techniques for managing fluence and focal condition of the laser beam, the coating layer(s) and the substrate material can be processed through ablation and internal modification, respectively. The internal modification can result in die separation.