Abstract: A semiconductor device has a first semiconductor wafer. The first semiconductor wafer is singulated to provide a first wafer section including at least one first semiconductor die or a plurality of first semiconductor die. The first wafer section is a fractional portion of the first semiconductor wafer. An edge support structure is formed around the first wafer section. A second wafer section includes at least one second semiconductor die. The second wafer section can be an entire second semiconductor wafer. The first semiconductor die is a first type of semiconductor device and the second semiconductor die is a second type of semiconductor device. An alignment opening is formed through the first wafer section and second wafer section with a light source projected through the opening. The first wafer section is bonded to the second wafer section with the first semiconductor die aligned with the second semiconductor die.

Abstract: The present invention relates to a process for direct bonding two substrates, comprising at least: (a) bringing the surfaces to be bonded of said substrates in close contact; and (b) propagating a bonding wave between said substrates, characterised in that said substrates are kept, during step (b), in an atmosphere of a gas having a negative Joule-Thomson coefficient at the temperature and pressure of said atmosphere.

Abstract: A semiconductor device includes a semiconductor chip, and a terminal connected with the semiconductor chip. The terminal has a first surface and a second surface spaced from each other in a thickness direction. The semiconductor device also includes a sealing resin covering the semiconductor chip and the terminal. The sealing resin is so configured that the first surface of the terminal is exposed from the sealing resin. The terminal is formed with an opening to be filled with the sealing resin.

Abstract: A first substrate provided with a receiving area made from a first metallic material is supplied. A second substrate provided with an insertion area comprising a base surface and at least two bumps made from a second metallic material is arranged facing the first substrate. The bumps are salient from the base surface. A pressure is applied between the first substrate and the second substrate so as to make the bumps penetrate into the receiving area. The first metallic material reacts with the second metallic material so as to form a continuous layer of an intermetallic compound having a base formed by the first and second metallic materials along the interface between the bumps and the receiving area.

Abstract: A method is disclosed which includes: forming at least one layer of material on at least part of a surface of a first substrate, wherein a first surface of the at least one layer of material is in contact with the first substrate thereby defining an interface; attaching a second substrate to a second surface of the at least one layer of material; forming bubbles at the interface; and applying mechanical force; whereby the second substrate and the at least one layer of material are jointly separated from the first substrate. Related arrangements are also described.

Abstract: Methods for hybrid wafer bonding. In an embodiment, a method is disclosed that includes forming a metal pad layer in a dielectric layer over at least two semiconductor substrates; performing chemical mechanical polishing on the semiconductor substrates to expose a surface of the metal pad layer and planarize the dielectric layer to form a bonding surface on each semiconductor substrate; performing an oxidation process on the at least two semiconductor substrates to oxidize the metal pad layer to form a metal oxide; performing an etch to remove the metal oxide, recessing the surface of the metal pad layer from the bonding surface of the dielectric layer of each of the at least two semiconductor substrates; physically contacting the bonding surfaces of the at least two semiconductor substrates; and performing a thermal anneal to form bonds between the metal pads of the semiconductor substrates. Additional methods are disclosed.

Abstract: A semiconductor package that includes a die with electrodes on opposite surfaces thereof and respective conductive clip electrically and mechanically coupled to the electrode and configured for vertical mounting of the package.

Abstract: A semiconductor light emitting device (10) comprises a semiconductor structure (12) comprising a first body (14) of a first semiconductor material (in this case Ge) comprising a first region of a first doping kind (in this case n) and a second body (18) of a second semiconductor material (in this case Si) comprising a first region of a second doping kind (in this case p). The structure comprises a junction region (15) comprising a first heterojunction (16) formed between the first body (14) and the second body (18) and a pn junction (17) formed between regions of the structure of the first and second doping kinds respectively. A biasing arrangement (20) is connected to the structure for, in use, reverse biasing the pn junction, thereby to cause emission of light.

Abstract: In an annealing process, a Kesterite film is provided on a substrate. The Kesterite film and the substrate are generally planar, have an interface, and have a substrate exterior side and a Kesterite exterior side. An additional step includes locating the cap adjacent the Kesterite exterior side. A further step includes applying sufficient heat to the Kesterite film and the substrate for a sufficient time to anneal the Kesterite film. The annealing is carried out with the cap adjacent the Kesterite exterior side. In another aspect, the film is not limited to Kesterite, and the cap is employed without any precursor layer thereon. Solar cell manufacturing techniques employing the annealing techniques are also disclosed.

Abstract: A method of manufacturing an electronic device on a plastic substrate includes: providing a carrier as a rigid support for the electronic device; providing a metallic layer on the carrier; forming the plastic substrate on the metallic layer, the metallic layer guaranteeing a temporary bonding of the plastic substrate to the carrier; forming the electronic device on the plastic substrate; and releasing the carrier from the plastic substrate. Releasing the carrier comprises immersing the electronic device bonded to the carrier in a oxygenated water solution that breaks the bonds between the plastic substrate and the metallic layer.

Abstract: Defects in a semiconductor substrate are reduced. A semiconductor substrate with fewer defects is manufactured with high yield. Further, a semiconductor device is manufactured with high yield. A semiconductor layer is formed over a supporting substrate with an oxide insulating layer interposed therebetween, adhesiveness between the supporting substrate and the oxide insulating layer in an edge portion of the semiconductor layer is increased, an insulating layer over a surface of the semiconductor layer is removed, and the semiconductor layer is irradiated with laser light, so that a planarized semiconductor layer is obtained. For increasing the adhesiveness between the supporting substrate and the oxide insulating layer in the edge portion of the semiconductor layer, laser light irradiation is performed from the surface of the semiconductor layer.

Abstract: A sealing and bonding material structure for joining semiconductor wafers having monolithically integrated components. The sealing and bonding material are provided in strips forming closed loops. There are provided at least two concentric sealing strips on one wafer. The strips are laid out so as to surround the component(s) on the wafers to be sealed off when wafers are bonded together. The material in the strips is a material bonding the semiconductor wafers together and sealing off the monolithically integrated components when subjected to force and optionally heating. A monolithically integrated electrical and/or mechanical and/or fluidic and/or optical device including a first substrate and a second substrate, bonded together with the sealing and bonding structure, and a method of providing a sealing and bonding material structure on at least one of two wafers and applying a force and optionally heat to the wafers to join them are described.

Abstract: A semiconductor-on-glass substrate having a relatively stiff (e.g. relatively high Young's modulus of 125 or higher) stiffening layer or layers placed between the silicon film and the glass in order to eliminate the canyons and pin holes that otherwise form in the surface of the transferred silicon film during the ion implantation thin film transfer process. The new stiffening layer may be formed of a material, such as silicon nitride, that also serves as an efficient barrier against penetration of sodium and other harmful impurities from the glass substrate into the silicon film.

Abstract: An LED array comprises a growth substrate and at least two separated LED dies grown over the growth substrate. Each of LED dies sequentially comprise a first conductive type doped layer, a multiple quantum well layer and a second conductive type doped layer. The LED array is bonded to a carrier substrate. Each of separated LED dies on the LED array is simultaneously bonded to the carrier substrate. The second conductive type doped layer of each of separated LED dies is proximate to the carrier substrate. The first conductive type doped layer of each of LED dies is exposed. A patterned isolation layer is formed over each of LED dies and the carrier substrate. Conductive interconnects are formed over the patterned isolation layer to electrically connect the at least separated LED dies and each of LED dies to the carrier substrate.

Abstract: Provided is a semiconductor device including: a base plate; a thermally conductive resin layer formed on an upper surface of the base plate; an integrated layer which is formed on an upper surface of the thermally conductive resin layer, and includes an electrode and an insulating resin layer covering all side surfaces of the electrode; and a semiconductor element formed on an upper surface of the electrode, in which the integrated layer is thermocompression bonded to the base plate through the thermally conductive resin layer. This semiconductor device excels in insulating properties and reliability.

Abstract: Various embodiments may be used for laser-based modification of target material of a workpiece while advantageously achieving improvements in processing throughput and/or quality. Embodiments of a method of processing may include focusing and directing laser pulses to a region of the workpiece at a pulse repetition rate sufficiently high so that material is efficiently removed from the region and a quantity of unwanted material within the region, proximate to the region, or both is reduced relative to a quantity obtainable at a lower repetition rate. Embodiments of an ultrashort pulse laser system may include at least one of a fiber amplifier or fiber laser. Various embodiments are suitable for at least one of dicing, cutting, scribing, and forming features on or within a semiconductor substrate. Workpiece materials may also include metals, inorganic or organic dielectrics, or any material to be micromachined with femtosecond, picosecond, and/or nanosecond pulses.

Abstract: A method of forming a compressible contact structure on a semi-conductor chip which comprises bonding a compressible polymer layer to the chip's surface, forming a plurality of openings within the layer, depositing electrically conductive material within the openings to form electrical connections with the chip's contacts, forming a plurality of electrically conductive line elements on the polymer layer extending from a respective opening and each including an end portion, and forming a plurality of contact members each on a respective one of the line segment end portions. The compressible polymer layer allows the contact members to deflect toward (compress) the chip when the contact members are engaged by an external force or forces. A semi-conductor chip including such a compressible contact structure is also provided.

Abstract: Method for manufacturing a rigid power module with a layer that is electrically insulating and conducts well thermally and has been deposited as a coating, the structure having sprayed-on particles that are fused to each other, of at least one material that is electrically insulating and conducts well thermally, having the following steps: manufacturing a one-piece lead frame; populating the lead frame with semiconductor devices, possible passive components, and bonding corresponding connections, inserting the thus populated lead frame into a compression mould so that accessibility of part areas of the lead frame is ensured, pressing a thermosetting compression moulding compound into the mould while enclosing the populated lead frame, coating the underside of the thus populated lead frame by thermal spraying in at least the electrically conducting areas and overlapping also the predominant areas of the spaces, filled with mold compound.

Abstract: A wafer bonding method includes providing a primary wafer and a plurality of secondary wafers, wherein the primary wafer is larger than the secondary wafers. An intermediate material layer is formed on at least one of a bonding surface of the primary wafer and bonding surfaces of the secondary wafers. The intermediate material layer has a thermal expansion coefficient greater than the thermal expansion coefficient of the primary wafer and the thermal expansion coefficient of the secondary wafers. The secondary wafers are bonded onto the primary wafer.

Abstract: A method of forming metal films includes preparing a substrate, on which an insulating layer and a metal layer formed of a first metal are exposed; and forming a metal capping layer by supplying an organic precursor of a second metal onto the substrate to deposit the second metal simultaneously on the insulating layer and the metal layer, wherein the second metal capping layer has different thicknesses on the insulating layer and the metal layer.

Abstract: The objective of the present invention is to offer a method for forming a conductive pattern on a substrate and solder protrusions on the conductive pattern. The pitch of the conductive pattern corresponds to the pitch of electrodes on a semiconductor chip.

Abstract: A method for bonding a semiconductor structure with a substrate and a high efficiency photonic device manufactured by using the same method are disclosed. The method comprises steps of: providing a semiconductor structure and a substrate; forming a composite bonding layer on the semiconductor structure; and bonding the substrate with the composite bonding layer on the semiconductor structure to form a composite alloyed bonding layer. The semiconductor structure includes a compound semiconductor substrate and a high efficiency photonic device is produced after the compound semiconductor substrate is removed. Besides, the composite bonding layer can be formed on the substrate or formed on both the semiconductor structure and substrate simultaneously.

Abstract: A method of forming integrated circuits includes providing a wafer that includes a plurality of dies; aligning a first top die to a first bottom die in the wafer; recording a first destination position of the first top die after the first top die is aligned to the first bottom die; bonding the first top die onto the first bottom die; calculating a second destination position of a second top die using the first destination position; moving the second top die to the second destination position; and bonding the second top die onto a second bottom die without any additional alignment action.

Abstract: A microstructure of the semiconductor on insulator type with different patterns is produced by forming a stacked uniform structure including a plate forming a substrate, a continuous insulative layer and a semiconductor layer. The continuous insulative layer is a stack of at least three elementary layers, including a bottom elementary layer, at least one intermediate elementary layer, and a top elementary layer overlying the semiconductor layer, where at least one of the bottom elementary layer and the top elementary layer being of an insulative material. In the stacked uniform structure, at least two patterns are differentiated by modifying at least one of the elementary layers in one of the patterns so that the elementary layer has a significantly different physical or chemical property between the two patterns, where at least one of the bottom and top elementary layer is an insulative material that remains unchanged.

Abstract: In estimating a curved surface model by approximating the shape of the board surface of a circuit board, auxiliary measurement spots are set other than measurement spots on the board surface, eligibility as a sampling displacement magnitude in estimating a curved surface model is determined according to a difference in a displacement magnitude from a work reference surface. When the sampling displacement magnitude is determined to be ineligible, a new measurement spot is reset. By this operation, a local increase and decrease in the displacement magnitude due to a discontinuity of the board surface exerts no influence on the estimation of the curved surface model, and the curved surface model approximated more closely to the shape of the actual board surface is estimated, leading to an improvement in the work quality with the working height adjusted to the proper height.

Abstract: Methods and apparatus for producing a semiconductor on glass (SiOG) structure include: subjecting an implantation surface of a donor semiconductor wafer to an ion implantation process to create an exfoliation layer in the donor semiconductor wafer; bonding the implantation surface of the exfoliation layer to a glass substrate using electrolysis; separating the exfoliation layer from the donor semiconductor wafer, thereby exposing at least one cleaved surface; and subjecting the at least one cleaved surface to a wet etching process.

Abstract: A reusable silicon substrate device for use with layer transfer process. The device has a reusable substrate having a surface region, a cleave region, and a total thickness of material. The total thickness of material is at least N times greater than a first thickness of material to be removed. In a specific embodiment, the first thickness of material to be removed is between the surface region and the cleave region, whereupon N is an integer greater than about ten. The device also has a chuck member adapted to hold a handle substrate member in place. The chuck member is configured to hold the handle substrate in a manner to facilitate bonding the handle substrate to the first thickness of material to be removed. In a preferred embodiment, the device has a mechanical pressure device operably coupled to the chuck member. The mechanical pressure device is adapted to provide a force to cause bonding of the handle substrate to the first thickness of material to be removed.

Abstract: Methods for packaging microelectronic devices and microelectronic devices formed using such methods are disclosed herein. One aspect of the invention is directed toward a method for packaging a microelectronic device that includes coupling an active side of a microelectronic die to a surface of a support member. The microelectronic die can have a backside opposite the active side, a peripheral side extending at least part way between the active side and the backside, and at least one through-wafer interconnect. The method can further include applying an encapsulant to cover a portion of the surface of the support member so that a portion of the encapsulant is laterally adjacent to the peripheral side, removing material from a backside of the microelectronic die to expose a portion of at least one through-wafer interconnect, and applying a redistribution structure to the backside of the microelectronic die.

Abstract: A wedge wedge wire loop is formed with the steps: a) lowering the capillary onto the first connection point and applying a predefined bond force and ultrasound for producing a wedge connection on the first connection point, b) raising the capillary by a predetermined distance D1 in an essentially vertical direction, c) moving the capillary laterally and downwards in order to bend the wire and press it against the wedge connection, d) raising the capillary and moving the capillary in order to form a wire loop and to attach the wire to the second connection point, and e) tearing off the wire.

Abstract: The present invention provides a substrate treating method including the steps of joining a one-side surface of a substrate to be treated to a support substrate, treating the substrate to be treated in the condition where the substrate to be treated is supported by the support substrate, and removing the support substrate from the substrate to be treated. The step of joining the substrate to be treated to the support substrate includes melting a joint bump formed on the substrate to be treated so as to join the substrate to be treated to the support substrate, and the step of removing the support substrate from the substrate to be treated includes polishing the support substrate so as to remove the support substrate.

Abstract: A thermal mechanical process for bonding a flip chip die to a substrate. The flip chip die includes a plurality of copper pillar bumps, each copper pillar bump of the plurality of copper pillar bumps having a copper portion attached to the die and a bonding cap attached to the copper portion. The process includes positioning the die on the substrate such that the bonding cap of each copper pillar bump of the plurality of copper pillar bumps contacts a corresponding respective one of a plurality of bonding pads on the substrate, and thermosonically bonding the die to the substrate.

Abstract: The invention relates to a method of bonding a polymer surface to an electrically conductive or semiconductive surface, which method is characterized in that it comprises: a) the electrografting of an organic film onto the conductive or semiconductive surface; and then b) an operation of bonding the polymer surface to the conductive or semiconductive surface thus grafted. It also relates to applications of this method and to structures obtained by its implementation.

Abstract: Semiconductor-on-insulator (SOI) structures, including large area SOI structures, are provided which have one or more regions composed of a layer of a substantially single-crystal semiconductor (e.g., doped silicon) attached to a support substrate composed of an oxide glass or an oxide glass-ceramic. The oxide glass or oxide glass-ceramic is preferably transparent and preferably has a strain point of less than 1000° C., a resistivity at 250° C. that is less than or equal to 1016 ?-cm, and contains positive ions (e.g., alkali or alkaline-earth ions) which can move within the glass or glass-ceramic in response to an electric field at elevated temperatures (e.g., 300-1000° C.). The bond strength between the semiconductor layer and the support substrate is preferably at least 8 joules/meter2. The semiconductor layer can include a hybrid region in which the semiconductor material has reacted with oxygen ions originating from the glass or glass-ceramic.

Abstract: An object of the invention is to make it possible to perform the embedding of a Cu diffusion preventing film and a Cu film to a fine pattern of a high aspect ratio by using a medium of a supercritical state in a manufacturing process of a semiconductor device. The object of the invention is achieved by a substrate processing method comprising a first step of processing a substrate by supplying a first processing medium containing a first medium of a supercritical state onto the substrate, a second step of forming a Cu diffusion preventing film on the substrate by supplying a second processing medium containing a second medium of a supercritical state onto the substrate, and a third step of forming a Cu film on the substrate by supplying a third processing medium containing a third medium of a supercritical state onto the substrate.

Abstract: An effect of metal contamination caused in manufacturing an SOI substrate can is suppressed. A damaged region is formed by irradiating a semiconductor substrate with hydrogen ions, and then, a base substrate and the semiconductor substrate are bonded to each other. Heat treatment is performed thereon to cleave the semiconductor substrate, so that an SOI substrate is manufactured. A gettering site layer is formed of a semiconductor containing a Group 18 element such as Ar, over a semiconductor layer of the SOI substrate. Heat treatment is performed thereon to perform gettering of a metal element in the semiconductor layer with the gettering site layer. By removing the gettering site layer by etching, thinning of the semiconductor layer can be performed.

Abstract: A semiconductor device with a chip (505), its position defining a plane, and an insulating substrate (503) with first and second surfaces; the substrate is substantially coplanar with the chip, without warpage. One of the chip sides is attached to the first substrate surface using adhesive material (504), which has a thickness. The thickness of the adhesive material is distributed so that the thickness (504b) under the central chip area is equal to or smaller than the material thickness (504a) under the peripheral chip areas. Encapsulation compound (701) is embedding all remaining chip sides and the portions of the first substrate surface, which are not involved in the chip attachment. When reflow elements (720) are attached to the substrate contact pads, they are substantially coplanar with the chip.

Abstract: A silicon direct bonding (SDB) method by which void formation caused by gases is suppressed. The SDB method includes: preparing two silicon substrates having corresponding bonding surfaces; forming trenches having a predetermined depth in at least one bonding surface of the two silicon substrates; forming gas discharge outlets connected to the trenches on at least one of the two silicon substrates to vertically penetrate the bonding surface; cleaning the two silicon substrates; closely contacting the two silicon substrates to each other; and thermally treating the two substrates to bond them to each other. The trenches are formed along at least a part of a plurality of dicing lines, and both ends of the trenches are clogged. Gases generated during a thermal treatment process can be smoothly and easily discharged through the trenches and the gas discharge outlet such that a void is prevented from being formed in the junctions of the two silicon substrates due to the gases.

Abstract: A method of forming a semiconductor on glass structure includes: establishing an exfoliation layer on a semiconductor wafer; contacting the exfoliation layer of the semiconductor wafer to a glass substrate; applying pressure, temperature and voltage to the semiconductor wafer and the glass substrate, without a vacuum atmosphere, such that a bond is established therebetween via electrolysis; and applying stress such that the exfoliation layer separates from the semiconductor wafer and remains bonded to the glass substrate.

Abstract: The present invention discloses a method that includes: providing two wafers; forming raised contacts on the two wafers; aligning the two wafers; bringing together the raised contacts; locally deflecting the two wafers; and bonding the raised contacts. The present invention also discloses a bonded-wafer structure that includes: a first wafer, the first wafer being locally deflected, the first wafer including a first raised contact; and a second wafer, the second wafer being locally deflected, the second wafer including a second raised contact, wherein the second raised contact is bonded to the first raised contact.

Abstract: A semiconductor device with a chip (505), its position defining a plane, and an insulating substrate (503) with first and second surfaces; the substrate is substantially coplanar with the chip, without warpage. One of the chip sides is attached to the first substrate surface using adhesive material (504), which has a thickness. The thickness of the adhesive material is distributed so that the thickness (504b) under the central chip area is equal to or smaller than the material thickness (504a) under the peripheral chip areas. Encapsulation compound (701) is embedding all remaining chip sides and the portions of the first substrate surface, which are not involved in the chip attachment. When reflow elements (720) are attached to the substrate contact pads, they are substantially coplanar with the chip.

Abstract: Semiconductor-on-insulator (SOI) structures, including large area SOI structures, are provided which have one or more regions composed of a layer (15) of a substantially single-crystal semiconductor (e.g., doped silicon) attached to a support substrate (20) composed of an oxide glass or an oxide glass-ceramic. The oxide glass or oxide glass-ceramic is preferably transparent and preferably has a strain point of less than 1000° C., a resistivity at 250° C. that is less than or equal to 1016 ?-cm, and contains positive ions (e.g., alkali or alkaline-earth ions) which can move within the glass or glass-ceramic in response to an electric field at elevated temperatures (e.g., 300–1000° C.). The bond strength between the semiconductor layer (15) and the support substrate (20) is preferably at least 8 joules/meter2. The semiconductor layer (15) can include a hybrid region (16) in which the semiconductor material has reacted with oxygen ions originating from the glass or glass-ceramic.