Abstract: A multichip module (MCM) has redundant I/O connections between its dice. That is, the number of inter-die I/O connections used is larger than the number of connections ordinarily used to provide connectivity between the dice. Defective connections are discovered through testing after MCM assembly and avoided, with signals being rerouted through good (e.g., not defective) redundant connections. The testing can be done at assembly time and the results stored in nonvolatile memory. Alternatively, the MCM can perform the testing itself dynamically, e.g., at power up, and use the test results to configure the inter-die I/O connections.

Abstract: A semiconductor die includes a substrate comprising a first layer of a first wide band gap semiconductor material having a first conductivity, a second layer of a second wide band gap semiconductor material having a second conductivity different from the first conductivity, in electrical contact with the first layer, a third layer of a third wide band gap semiconductor material having a third conductivity different from the first conductivity and second conductivity, in electrical contact with the second layer, a fourth layer of a fourth wide band gap semiconductor material having the second conductivity, in electrical contact with the third layer, and a fifth layer of a fifth wide band gap semiconductor material having the first conductivity and in electrical contact with the fourth layer, wherein the first layer, the second layer, the third layer, the fourth layer, and the fifth layer are sequentially arranged to form a structure.

Abstract: A plurality of diode/resistor devices are formed within an integrated circuit structure using manufacturing equipment operatively connected to a computerized machine. Each of the diode/resistor devices comprises a diode device and a resistor device integrated into a single structure. The resistance of each of the diode/resistor devices is measured during testing of the integrated circuit structure using testing equipment operatively connected to the computerized machine. The current through each of the diode/resistor devices is also measured during testing of the integrated circuit structure using the testing equipment. Then, response curves for the resistance and the current are computed as a function of variations of characteristics of transistor devices within the integrated circuit structure and/or variations of manufacturing processes of the transistor devices within the integrated circuit structure.

Abstract: In one embodiment, a packaging solution for an application integrated circuit (IC) and one or more other ICs is provided. The packaging solution may support both chip-on-chip packaging of the application IC (in flip-chip connection to a package substrate) and other ICs (in non-flip chip orientation), and package-on-package packaging of the application IC and the other ICs. The package substrate may include a first set of pads proximate to the application IC to support chip-on-chip connection to the other ICs. The pads may be connected to conductors that extend underneath the application IC, to connect to the application IC. A second set of pads may be connected to package pins for package-on-package solutions. If the chip-on-chip solution proves reliable, support for the package-on-package solution may be eliminated and the package substrate may be reduced in size.

Abstract: Exemplary semiconductor device packaging structure and packaging method are provided. The packaging method uses an adhesive layer to bond multiple wafer pieces onto a first surface of a carrier substrate, each adjacent two of the wafer pieces having a gap formed therebetween for exposing a part of the adhesive layer. A packaging layer is filled in each of the gaps. At least one through silicon via is formed each of the wafer pieces to expose a bonding pad formed on an active surface of the wafer pieces. Redistribution circuit layers are formed on back surfaces of the respective wafer pieces and filled into the through silicon vias for electrical connection with the bonding pads. A sawing process is performed to saw starting from each of the packaging layers to a second surface of the carrier substrate, and thereby multiple semiconductor device packaging structures are obtained.

Abstract: Electrical testing of metal oxide semiconductor (MOS) high-k capacitor structures is used to evaluate photoresist strip or cleaning chemicals using a combinatorial workflow. The electrical testing can be able to identify the damages on the high-k dielectrics, permitting a selection of photoresist strip chemicals to optimize the process conditions in the fabrication of semiconductor devices. The high productivity combinatorial technique can provide a compatibility evaluation of photoresist strip chemicals with high-k devices.

Abstract: A liquid crystal display (LCD) module is disclosed, which comprises a thin film transistor (TFT) substrate and a color filter (CF) substrate disposed opposite to each other, and a liquid crystal layer sandwiched between the TFT substrate and the CF substrate. The TFT substrate comprises a plurality of transmission test units and a plurality of wires. The CF substrate comprises a plurality of curing test units insulated from each other, and each of the curing test units is electrically connected to one of the wires via one of the transmission test units. An LCD device and a manufacturing method of an LCD module are further disclosed. The LCD device, the LCD module and the manufacturing method thereof according to the present disclosure can avoid occurrence of arcing in the TFT substrate during the CVD process, thereby improving the product yield and reducing the manufacturing cost.

Abstract: Methods of fabricating integrated circuit devices utilize fuse elements to support sequential testing of vertically-integrated test elements during fabrication. These methods include forming a first test element, a first fuse and a first test pad electrically connected by the first fuse to the first test element, on a substrate. The first test element is tested by passing a first current between the first test element and first test pad and through the first fuse. The first fuse is then “cut” by increasing an impedance of the first fuse, which may include breaking the first fuse to create an electrical “open” (infinite impedance) or greatly increasing a resistance of the first fuse (e.g., by narrowing the fuse through electromigration). A second test element and a second test pad, which is electrically connected to the second test element and the first test pad, are then formed on the substrate.

Abstract: In a method of manufacturing a semiconductor device using an electron beam lithography apparatus configured to emit an electron beam to perform lithography of a pattern, processing including pattern formation with the electron beam lithography apparatus is performed on a wafer, and an electric characteristic of the thus manufactured semiconductor devices is measured by a semiconductor testing apparatus. Then, electron beam lithography data to be used by the electron beam lithography apparatus is adjusted based on a result of measurement of the electric characteristic so as to reduce a variation in the electric characteristic of the semiconductor device within a surface of the wafer.

Abstract: The manufacturing efficiency of semiconductor devices is improved. A plurality of external terminals (leads) electrically coupled with a semiconductor chip, and contact regions of a plurality of terminals (test terminals) are brought into contact with each other, respectively. This establishes an electrical coupling between the semiconductor chip and a test circuit. Thus, an electrical test is performed. Herein, the terminals are to be repeatedly used in the electrical test of a plurality of semiconductor devices. Whereas, the contact region of the terminal includes a core material formed of a first alloy, and a metal film covering the core material. Further, the metal film is formed of a second alloy higher in hardness than the first alloy.

Abstract: A semiconductor wafer includes a plurality of semiconductor chips having bonding pads; and a connection wiring line coupling the plurality of semiconductor chips such that a test signal, which is inputted through bonding pads of an arbitrary semiconductor chip among the plurality of semiconductor chips, is transmitted to bonding pads of other semiconductor chips among the plurality of semiconductor chips.

Abstract: A multi-chip package may include a first semiconductor chip, a second semiconductor chip, a first stud bump, a first nail head bonding bump, a second stud bump, and a first conductive wire. The first semiconductor chip may have a first bonding pad. The second semiconductor chip may be stacked on the first semiconductor chip so the first bonding pad remains exposed. The second semiconductor chip may have a second bonding pad. The first stud bump may be formed on the first bonding pad. The first nail head bonding bump may be formed on the first stud bump, with one end of a first conductive wire formed between the two. The second stud bump may be formed on the second bonding pad, with another end of the first conductive wire formed between the two. An electrical connection test may be performed on each of the wire bonding processes.

Abstract: A method for producing semiconductor device includes: performing first, second and third exposures of a photoresist film formed on a semiconductor wafer via a mask; wherein: first, second and third shot regions respectively defined by the first, second and third exposures are aligned in a first direction; the mask has a shot region including a peripheral scribe region having a first and second side crossing the first direction; the photoresist film is of positive type, a first pattern is formed as a light shielding pattern disposed on the first side, and a second pattern is formed as a light transmitting region disposed on the second side; the first and second exposures are performed in such a manner that the first and second patterns do not overlap each other; and the second and third exposures are performed in such a manner that the first and second patterns overlap each other.

Abstract: An automatic analyzer detects voltage applied across electrodes, and judges whether voltage value falls within set voltage range. When the detected voltage value is lower than minimum value of set voltage range, the analyzer calculates the deficient amount of base solution based on the detected voltage value, controls a valve to supply the deficient amount of base solution, then, performs operation control of the valve so as to keep the prescribed amount of plating solution in plating solution tank, and discharges plating solution. When the detected voltage value is higher than maximum value of set voltage range, the analyzer calculates the excess amount of base solution based on the detected voltage value, controls a valve, and supplies pure water into the tank so that the base solution concentration falls within prescribed range to dilute plating solution, then controls a valve, and discharges plating solution so as to keep prescribed amount.

Abstract: The semiconductor wafer for a silicon-on-insulator integrated circuit comprises an insulating region located between a first semiconductor substrate intended to receive the integrated circuit and a second semiconductor substrate containing at least one buried layer comprising at least one metal silicide.

Abstract: In wafer probe inspection for a flip-chip semiconductor device having a solder bump, electric test may be performed at a high temperature by causing a probe needle to directly contact a solder bump over a wafer. The inventors have examined such high temperature probe tests in various ways and revealed the following problems. When a high temperature probe test is performed at 90° C. or higher using a palladium alloy probe needle, tin diffusion due to a solder bump occurs at the needle point to raise resistance, resulting in causing open failure. According to the invention of the present application, at least the tip of a palladium-based probe needle has mainly a granular grain structure in a high temperature probe test performed with the palladium-based probe needle contacting a solder bump electrode over a semiconductor wafer.

Abstract: A leakage measurement structure for through substrate vias which includes a semiconductor substrate; a plurality of through substrate vias in the semiconductor substrate extending substantially through the semiconductor substrate; and a leakage measurement structure located in the semiconductor substrate. The leakage measurement structure includes a plurality of substrate contacts extending into the semiconductor substrate; a plurality of sensing circuits connected to the plurality of through substrate vias and to the plurality of the substrate contacts, the plurality of sensing circuits providing a plurality of outputs indicative of current leakage from the plurality of through substrate vias; a built-in self test (BIST) engine to step through testing of the plurality of through substrate vias; and a memory coupled to the BIST engine to receive the outputs from the plurality of sensing circuits.

Abstract: Electrical devices comprised of nanowires are described, along with methods of their manufacture and use. The nanowires can be nanotubes and nanowires. The surface of the nanowires may be selectively functionalized Nanodetector devices are described.

Abstract: A semiconductor structure including a test structure for detection of a gap in a conductive layer of the semiconductor structure includes a semiconductor substrate; the test structure, the test structure being located on the semiconductor substrate, the test structure comprising a multilayer gate stack, wherein the multilayer gate stack includes a single conductive layer region including: a gate dielectric located on the semiconductor substrate; the conductive layer located on the gate dielectric; and an undoped amorphous silicon layer located on the conductive layer; and wherein the test structure is configured to detect the presence of the gap in the conductive layer.

Abstract: A laser diode includes a junction surface configured to interface with an integrated optics slider. Cathode and anode electrical junctions are disposed on the junction surface. The cathode and anode electrical junctions are configured for electrical and mechanical coupling to the integrated optics slider. At least one test pad is disposed on the junction surface that is physically separate from and electrically coupled to one of the cathode and anode electrical junctions. The test pad is configured to be contacted by a test probe and is not configured for electrical or mechanical coupling to the integrated optics slider.

Abstract: An optoelectronic device including at least one of a solar device, a semiconductor device, and an electronic device. The device includes a semiconductor unit. A plurality of metal fingers is disposed on a surface of the semiconductor unit for electrical conduction. Each of the metal fingers includes a pad area for forming an electrical contact. The optoelectronic device includes a plurality of pad areas that is available for connection to a bus bar, wherein each of the metal fingers is connected to a corresponding pad area for forming an electrical contact.

Abstract: A semiconductor apparatus includes a semiconductor chip through-line for transmitting signals commonly to a plurality of stacked semiconductor chips. The apparatus includes a first test pulse signal transmission unit configured to transmit a first test pulse signal to a first end of the semiconductor chip through-line when a power-up operation is performed; a second test pulse signal transmission unit configured to transmit a second test pulse signal to a second end of the semiconductor chip through-line after the first test pulse signal is transmitted; a first signal reception unit coupled to the first end of the semiconductor chip through-line, and configured to receive signals transmitted from the first and second test pulse signal transmission units; and a second signal reception unit coupled to the second end of the semiconductor chip through-line, and configured to receive the signals transmitted by the first and second test pulse signal transmission units.

Abstract: A circuit architecture provides for the parallel supplying of power during electric or electromagnetic testing of electronic devices integrated on a same semiconductor wafer and bounded by scribe lines. The circuit architecture comprises a conductive grid interconnecting the electronic devices and having a portion external to the devices and a portion internal to the devices. The external portion extends along the scribe lines; and the internal portion extends within at least a part of the devices. The circuit architecture includes interconnection pads between the external portion and the internal portion of the conductive grid and provided on at least a part of the devices, the interconnection pads forming, along with the internal and external portions, power supply lines which are common to different electronic devices of the group.

Abstract: A thin-film transistor (TFT) substrate includes a base substrate, a test pad and a test pad line. The base substrate includes a display area including a data line and a TFT, a peripheral area including a common voltage line, and a test area disposed outside of the peripheral area. The test pad is disposed in the test area and electrically connected to the data line. The test pad line connects the data line with the test pad and crosses the common voltage line.

Abstract: An apparatus including a first layer configured to enable a flow of charge carriers from a source electrode to a drain electrode, a second layer configured to control the density of charge carriers in the first layer using an electric field formed between the first and second layers, and a third layer positioned between the first and second layers to shield the first layer from the electric field, wherein the third layer includes a layer of electrically conducting nanoparticles and is configured such that when stress is applied to the third layer, the strength of the electric field experienced by the first layer is varied resulting in a change in the charge carrier density and a corresponding change in the conductance of the first layer.

Abstract: A method performs electrical testing and assembly of an electronic device on a wafer and comprising a pad made in an oxide layer covered by a passivation layer. The method includes connecting the electronic device to a testing apparatus; providing said electronic device with a metallization layer extending on the passivation layer from the pad to a non-active area of said wafer. The method comprises-performing the electrical testing on wafer of the electronic device by placing a probe of on a portion of the extended metallization layer; performing the cut of said wafer, reducing the extension of the metallization layer to the edge of the electronic device; embedding the device inside a package, forming on the metallization layer an electrical connection configured to connect the metallization layer to a circuit in said package.

Abstract: The production method for the oxidized carbon thin film of the present disclosure includes: a first step of preparing a carbon thin film and iron oxide that is in contact with the carbon thin film and contains Fe2O3; and a second step of forming an oxidized carbon thin film having an oxidized portion composed of oxidized carbon by applying a voltage or current between the carbon thin film and the iron oxide with the carbon thin film side being positive and thereby oxidizing a contact portion of the carbon thin film with the iron oxide to change it into the oxidized portion. This production method allows a pattern of nanometer order to be formed on a carbon thin film represented by graphene. The method causes less damage to the formed pattern and has high affinity with a semiconductor process, thereby enabling a wide range of applications as a process technique for producing an electronic device.

Abstract: A semiconductor device includes a semiconductor substrate including an element region, an inner sealing and an outer sealing which are formed on the element region and have a first opening part and a second opening part, respectively, a multilayer interconnection structure which is formed on the substrate and stacks multiple inter-layer insulation films each including a wiring layer, a moisture resistant film formed between a first inter-layer insulation film and a second inter-layer insulation film which are included in the multilayer interconnection structure, a first portion which extended from a first side of the moisture resistant film and passes the first opening part, a second portion which extended from a second side of the moisture resistant film and passes through the second opening part, and a wiring pattern including a via plug which penetrates the moisture resistant film and connects the first portion and the second portion.

Abstract: A semiconductor package includes a substrate, at least one chip including a first side and a backside opposite of the first side, the first side electrically coupled to the substrate, a conductive layer coupled to the backside of the at least one chip, and at least one electronic component coupled to the conductive layer and in electrical communication with the substrate.

Abstract: The present invention relates generally to assembly techniques. According to the present invention, the alignment and probing techniques to improve the accuracy of component placement in assembly are described. More particularly, the invention includes methods and structures to detect and improve the component placement accuracy on a target platform by incorporating alignment marks on component and reference marks on target platform under various probing techniques. A set of sensors grouped in any array to form a multiple-sensor probe can detect the deviation of displaced components in assembly.

Abstract: A method includes communicatively coupling first and second integrated electronic devices together through a plurality of reference capacitors, transmitting a plurality of transmission reference signals on transmission reference electrodes of the plurality of reference capacitors, receiving coupling signals on reception reference electrodes of the plurality of reference capacitors, amplifying said coupling signals, generating a plurality of reception reference signals, generating a plurality of reception control signals as a function of the plurality of reception reference signals, and detecting a possible misalignment between said first and second integrated electronic devices based on the plurality of reception control signals.

Abstract: In a method of manufacturing of a semiconductor device according to an embodiment, an inspection transistor is subjected to silicidation and subsequently a characteristic of the inspection transistor is measured after the inspection transistor and a product transistor on a substrate are subjected to an annealing process. Thereafter, based on the measured characteristic, a characteristic adjustment annealing process to make a characteristic of the product transistor close to a desired characteristic is performed, and then the product transistor is subjected to silicidation.

Abstract: An apparatus and method for electrical mask inspection is disclosed. A scan chain is formed amongst two metal layers and a via layer. One of the three layers is a functional layer under test, and the other two layers are test layers. A resistance measurement of the scan chain is used to determine if a potential defect exists within one of the vias or metal segments comprising the scan chain.

Abstract: According to one exemplary embodiment, a method for adjusting geometry of a capacitor includes fabricating a first composite capacitor residing in a first standard cell with a first set of process parameters. The method further includes using a second standard cell having substantially same dimensions as the first standard cell. The method further includes using a capacitance value from the first composite capacitor to adjust a geometry of a second composite capacitor residing in the second standard cell, wherein the second composite capacitor is fabricated with a second set of process parameters. The geometry of the second composite capacitor can be adjusted to cause the second composite capacitor to have a capacitance value substantially equal to the capacitance value from the first composite capacitor.

Abstract: A method and structure for uncovering captive devices in a bonded wafer assembly comprising a top wafer and a bottom wafer. One embodiment method includes forming a plurality of cuts in the top wafer and removing a segment of the top wafer defined by the plurality of cuts. The bottom wafer remains unsingulated after the removal of the segment.

Abstract: A semiconductor device includes a substrate, an insulator layer on the substrate, an inductor on the insulator layer, and a film including a ferromagnetic particle on the inductor.

Abstract: An embodiment for manufacturing an electronic circuit forms at least one first structure on a semiconductor substrate, determines at least one electrically defined characteristic of the at least one first structure, selects a reticle corresponding to the measured characteristic, and forms at least one additional structure on the semiconductor substrate with the selected reticle.

Abstract: An integrated circuit and method for making an integrated circuit including doping a semiconductor body is disclosed. One embodiment provides defect-correlated donors and/or acceptors. The defects required for this are produced by electron irradiation of the semiconductor body. Form defect-correlated donors and/or acceptors with elements or element compounds are introduced into the semiconductor body.

Abstract: A semiconductor device which uses a semiconductor substrate having a TEG pattern to reduce defects induced by dicing. The semiconductor device includes a semiconductor substrate which is to be or has been divided into individual semiconductor chips by dicing; an interlayer insulating layer formed over the semiconductor substrate; a seal ring provided in the interlayer insulating layer and formed along the periphery of the semiconductor chip; and a TEG wiring having one end coupled to the seal ring and the other end extending toward an end face of the periphery of the semiconductor chip.

Abstract: According to one exemplary embodiment, a method for adjusting geometry of a capacitor includes fabricating a first composite capacitor residing in a first standard cell with a first set of process parameters. The method further includes using a second standard cell having substantially same dimensions as the first standard cell. The method further includes using a capacitance value from the first composite capacitor to adjust a geometry of a second composite capacitor residing in the second standard cell, wherein the second composite capacitor is fabricated with a second set of process parameters. The geometry of the second composite capacitor can be adjusted to cause the second composite capacitor to have a capacitance value substantially equal to the capacitance value from the first composite capacitor.

Abstract: Various embodiments of light emitting devices with efficient wavelength conversion and associated methods of manufacturing are described herein. In one embodiment, a light emitting device includes a first semiconductor material, a second semiconductor material spaced apart from the first semiconductor material, and an active region between the first and second semiconductor materials. The active region is configured to produce a light via electroluminescence. The light emitting device also includes a conversion material on the second semiconductor material, the conversion material containing aluminum gallium indium phosphide (AlGaInP) doped with an N-type dopant.

Abstract: The disclosure relates to a method of fabricating an integrated circuit of CMOS technology in a semiconductor wafer comprising scribe lines. According to the disclosure, a ground contact pad of the integrated circuit is made in a scribe line of the wafer and is destroyed during a step of individualizing the integrated circuit by singulation of the wafer. A ground contact of the integrated circuit is made on the back side of the integrated circuit when it is assembled in an interconnection package.

Abstract: A wafer level integration module and method for fabricating are disclosed according to a construction whereby semiconductor functional device fabrication is carried out only after interconnect structures are processed on a bare wafer. The fabrication and processing include forming interconnect structures in a first side of a wafer. An insulation layer is deposited on the first side of the wafer. A conductive layer is deposited on the insulation layer so as to fill the interconnect structures and contact the insulation layer on the walls thereof. The conductive layer on the interconnect structures forms interconnection contacts on the first side of the wafer and interconnection vias extending into the wafer. The conductive layer including the interconnection contacts is exposed on the first side of the wafer. A semiconductor functional device is fabricated on the first side of the wafer and interconnected with the interconnection contacts during the fabricating.

Abstract: A method of silicon wafer alignment used in through-silicon-via interconnection for use in the field of high-integrity packaging technology is disclosed. In one aspect, the method includes aligning and calibrating the upper and lower silicon wafers, stacked and interconnected electrically, so as to improve alignment accuracy of silicon wafers and reduce interconnection resistances. In some embodiments, the integrated circuit chip made by the method improves speed and energy performance.

Abstract: A method for manufacturing a semiconductor device wherein a semiconductor element is sealed with mold resin, a MOS structure is on an upper side of the semiconductor chip, and a PN junction region is on a back side of the semiconductor chip, comprises: obtaining an in-plane distribution of impurity concentration of the PN junction region in the semiconductor chip before encapsulation so that an in-plane distribution of breakdown voltage and leakage current of the semiconductor chip become uniform after encapsulation; forming the PN junction region having the obtained in-plane distribution of impurity concentration on the back side of the semiconductor chip; and sealing the semiconductor chip with the resin after forming the PN junction region.

Abstract: A system and method for preconditioning a photovoltaic device is described. One embodiment includes a method for preconditioning a photovoltaic device, the method comprising applying a forward-bias to the photovoltaic device, wherein a forward-bias current is equal to or greater than IMP(FB) for the photovoltaic device.

Abstract: The present disclosure relates to a structure comprising 1. an electrically conductive substrate having carbon nanotubes grown thereon; 2. a cured polymeric fill matrix comprising at least one latent photoacid generator embedded around the carbon nanotubes but allowing tips of the carbon nantotubes to be exposed; 3. a layer of patterned and cured photosensitive dielectric material on the cured polymeric fill matrix, wherein tips of the carbon nantobues are exposed within the patterns; and 4. an electrically conductive material filled into the interconnect pattern and in contact with the exposed tips of the carbon nanotubes; and to methods of making the structure and using the structure to measure the electrical characteristics of carbon nanotubes.

Abstract: A method of determining the reliability of a high-voltage PMOS (HVPMOS) device includes determining a bulk resistance of the HVPMOS device, and evaluating the reliability of the HVPMOS device based on the bulk resistance.

Abstract: A three dimensional (3D) integrated circuit (IC) testing apparatus comprises a plurality of connection devices. When a device under test (DUT) such as an interposer or a 3D IC formed by a plurality of 3D dies operates in a testing mode, the 3D IC testing apparatus is coupled to the DUT via a variety of interface channels such as probes. The connection devices and a variety of through silicon vias (TSVs) in the DUT form a TSV chain so that a electrical characteristic test of the variety of TSVs can be tested all at once.

Abstract: In one disclosed embodiment, the present test structure for determining gate-to-body current in a floating body FET includes a floating body FET situated over a semiconductor layer, where the floating body FET includes a first gate and first and second source/drain regions. The floating body test structure further includes a second gate and a first contact situated over the first source/drain region. A gate-to-channel current measured between the second gate and the first contact is utilized to determine the gate-to-body tunneling current. The gate-to-body tunneling current can be determined by subtracting the gate-to-channel current from twice a source/drain current of the floating body FET. The test structure may also include a second contact situated on a doped region in the semiconductor layer, where a diode current flow through the doped region determines a body voltage for the floating body FET.