Abstract: An electronic apparatus includes a semiconductor substrate, a device structure supported by the semiconductor substrate, and a guard ring surrounding the device structure. The guard ring includes a plurality of conductive structures spaced apart from one another, supported by the semiconductor substrate, and coupled to a voltage source to establish an operating voltage for the guard ring.

Abstract: Power consumption of electronic components is reduced, particularly in a multi-chip package. Embodiments reduce parasitic capacitance of a semiconductor chip by reducing ESD protection circuitry that is not needed during operation of the package. ESD protection circuitry would be operational during production and/or testing of the chip, but some circuitry would be disabled or removed prior to normal operation of the multi-chip package.

Abstract: Embodiments of a Silicon Nitride (SiN) passivation structure for a semiconductor device and methods of fabrication thereof are disclosed. In general, a semiconductor device includes a semiconductor body and a SiN passivation structure over a surface of the semiconductor body. In one embodiment, the SiN passivation structure includes one or more Hydrogen-free SiN layers on, and preferably directly on, the surface of the semiconductor body, a Hydrogen barrier layer on, and preferably directly on, a surface of the one or more Hydrogen-free SiN layers opposite the semiconductor body, and a Chemical Vapor Deposition (CVD) SiN layer on, and preferably directly on, a surface of the Hydrogen barrier layer opposite the one or more Hydrogen-free SiN layers. The Hydrogen barrier layer preferably includes one or more oxide layers of the same or different compositions. Further, in one embodiment, the Hydrogen barrier layer is formed by Atomic Layer Deposition (ALD).

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. Also included is a method of testing a semiconductor substrate.

Abstract: Electronic assemblies and their manufacture are described. One assembly includes a coreless substrate comprising a plurality of dielectric layers and electrically conductive pathways, the coreless substrate including a first side and a second side opposite the first side. The assembly includes a first die embedded in the coreless substrate, the first die comprising an RF die, the first die positioned in a dielectric layer that extends to the first side of the coreless substrate. The assembly includes a second die positioned on first side, the second die positioned on the first die. In another aspect, a molding material may be positioned on the die side, wherein the first die and the second die are covered by the molding material. In another aspect, an electrical shielding layer may be positioned over the first side. Other embodiments are described and claimed.

Abstract: Provided is a method of fabricating a semiconductor device that includes providing a semiconductor substrate having a front side and a back side, forming a first circuit and a second circuit at the front side of the semiconductor substrate, bonding the front side of the semiconductor substrate to a carrier substrate, thinning the semiconductor substrate from the back side, and forming an trench from the back side to the front side of the semiconductor substrate to isolate the first circuit from the second circuit.

Abstract: A device includes a High-Voltage N-Well (HVNW) region have a first edge, and a High-Voltage P-Well (HVPW) region having a second edge adjoining the first edge. A first Shallow N-well (SHN) region is disposed over a lower portion of the HVNW region, wherein the first SHN region is spaced apart from the first edge by an upper part of the HVNW region. A second SHN region is disposed over a lower portion of the HVPW region, wherein the second SHN region is laterally spaced apart from the second edge. A Shallow P-well (SHP) region is disposed over the lower portion of the HVPW region, and is between the first SHN region and the second SHN region. The SHP region has a p-type impurity concentration higher than a p-type impurity concentration of the HVPW region. An isolation region is disposed over and contacting the SHP region.

Abstract: A method of arranging pads in a semiconductor memory device, the semiconductor memory device using the method, and a processing system having mounted therein the semiconductor memory device. The method includes classifying pads provided in a memory chip of the semiconductor memory device into monitoring pads configured for a memory chip test on a wafer, a package pads configured for wire connection in a package, and common pads configured for both the memory chip test on the wafer and wire connection in the package and arranging the monitoring pads and the package pads separately in columns on the memory chip.

Abstract: The present disclosure provides a semiconductor device including: a semiconductor identifier holding portion configured to hold a semiconductor identifier for identifying a semiconductor device; and a control portion configured such that upon elapse of a predetermined time period following receipt of an externally input instruction to hold the semiconductor identifier, the control portion issues an instruction to the semiconductor device immediately downstream of the semiconductor device to hold a semiconductor identifier of the immediately downstream semiconductor device and that during the time period between the point in time at which the externally input instruction is received and the point in time at which the instruction is issued to the immediately downstream semiconductor device to hold the semiconductor identifier thereof, the control portion causes the semiconductor identifier holding portion to hold the externally input identifier.

Abstract: The present disclosure relates to a secure device having a physical unclonable function and methods of manufacturing such a secure device. The device includes a substrate and at least one high-k/metal gate device formed on the substrate. The at least one high-k/metal gate device represents the physical unclonable function. In some cases, the at least one high-k/metal gate device may be subjected a variability enhancement. In some cases, the secure device may include a measurement circuit for measuring a property of the at least one high-k/metal gate device.

Abstract: A method for process control is disclosed. The method includes performing an etching process on a semiconductor substrate forming a structure and a test structure having a pattern and a releasing mechanism coupled to the pattern; and monitoring the pattern of the test structure to determine whether the etching process is complete.

Abstract: A semiconductor wafer having a multi-layer wiring structure is disclosed. The wafer comprises a plurality of chip die areas arranged on the wafer in an array and scribe line areas between the chip die areas. The scribe lines of a semiconductor wafer having USG top-level wiring layers above ELK wiring layers have at least one metal film structures substantially covering corner regions where two scribe lines intersect to inhibit delamination at the USG/ELK interface during wafer dicing operation.

Abstract: A semiconductor wafer contains a plurality of semiconductor die separated by a saw street. A contact pad is formed over an active surface of the semiconductor die. A protective pattern is formed over the active surface of the semiconductor die between the contact pad and saw street of the semiconductor die. The protective pattern includes a segmented metal layer or plurality of parallel segmented metal layers. An insulating layer is formed over the active surface, contact pad, and protective pattern. A portion of the insulating layer is removed to expose the contact pad. The protective pattern reduces erosion of the insulating layer between the contact pad and saw street of the semiconductor die. The protective pattern can be angled at corners of the semiconductor die or follow a contour of the contact pad. The protective pattern can be formed at corners of the semiconductor die.

Abstract: To provide a method for manufacturing a large-area semiconductor device, to provide a method for manufacturing a semiconductor device with high efficiency, and to provide a highly-reliable semiconductor device in the case of using a large-area substrate including an impurity element. A plurality of single crystal semiconductor substrates are concurrently processed to manufacture an SOI substrate, so that an area of a semiconductor device can be increased and a semiconductor device can be manufactured with improved efficiency. In specific, a series of processes is performed using a tray with which a plurality of semiconductor substrates can be concurrently processed. Here, the tray is provided with at least one depression for holding single crystal semiconductor substrates.

Abstract: A semiconductor integrated circuit includes at least one second semiconductor chip configured to generate an internal voltage, and a first semiconductor chip including a monitoring unit configured to monitor the internal voltage, and a first pad configured to provide monitoring result information outputted from the monitoring unit to a test device.

Abstract: A seal ring structure is formed through a multilayer structure of a plurality of dielectric films in a peripheral part of a chip region to surround the chip region. A dual damascene interconnect in which an interconnect and a plug connected to the interconnect are integrated is formed in at least one of the dielectric films in the chip region. Part of the seal ring structure formed in the dielectric film in which the dual damascene interconnect is formed is continuous. A protection film formed on the multilayer structure has an opening on the seal ring. A cap layer connected to the seal ring is formed in the opening.

Abstract: The present disclosure relates to a structure and method to create a self-repairing dielectric material for semiconductor device applications. A porous dielectric material is deposited on a substrate, and exposed with treating agent particles such that the treating agent particles diffuse into the dielectric material. A dense non-porous cap is formed above the dielectric material which encapsulates the treating agent particles within the dielectric material. The dielectric material is then subjected to a process which creates damage to the dielectric material. A chemical reaction is initiated between the treating agent particles and the damage, repairing the damage. A gradient concentration resulting from the consumption of treating agent particles by the chemical reaction promotes continuous diffusion the treating agent particles towards the damaged region of the dielectric material, continuously repairing the damage.

Abstract: A method is provided to create a proof mass supported by a dual-suspension system for Micro-Electro-Mechanical Systems (MEMS) using crystalline silicon. The pre-fabricated cavity method decreases the subsequent processing required to create the final mechanical structure including the proof mass and dual-suspension system. During processing, the proof mass may be connected to a support structure via tethered regions, which are removed subsequent to proof mass formation.

Abstract: In one embodiment, a semiconductor device includes a substrate, and a plurality of interconnects provided in the same interconnect layer above the substrate. The device further includes a plurality of insulators provided so as to be buried between the plurality of interconnects. Moreover, the plurality of interconnects include an interconnect group in which 2N or more interconnects are successively arrayed so that correlation coefficients of line edge roughness (LER) between both side surfaces of the respective interconnects are positive, where N is an integer of 4 or more.

Abstract: Embodiments include a light emitting device package. The light emitting device package comprises a housing including a cavity; a light emitting device positioned in the cavity; a lead frame including a first section electrically connected to the light emitting device in the cavity, a second section, which penetrates the housing, extending from the first section and a third section, which is exposed to outside air, extending from the second section; and a metal layer positioned on an area defined by a distance which is distant from the housing in the second section of the lead frame.

Abstract: A bidirectional protection component formed in a semiconductor substrate of a first conductivity type including a first implanted area of the first conductivity type, an epitaxial layer of the second conductivity type on the substrate and the first implanted area, a second area of the first conductivity type on the external side of the epitaxial layer, in front of the first area, and implanted with the same dose as the first area, a first metallization covering the entire lower surface of the substrate, and a second metallization covering the second area.

Abstract: The present invention provides a technique for improving the reliability of a semiconductor device where spreading of cracking that occurs at the time of dicing to a seal ring can be restricted even in a semiconductor device with a low-k film used as an interlayer insulating film. Dummy vias are formed in each layer on a dicing region side. The dummy vias are formed at the same intervals in a matrix as viewed in a top view. Even in the case where cracking occurs at the time of dicing, the cracking can be prevented from spreading to a seal ring by the dummy vias. As a result, resistance to moisture absorbed in a circuit formation region can be improved, and deterioration in reliability can be prevented.

Abstract: A semiconductor processing method that can generate a hole with different diameters, comprising: providing first material and second material different from the first material; and utilizing a etching process to etch the first material and the second material to form a hole through the first material and the second material; wherein the etching process has different etching rates for the first material and the second material such that the hole have different diameters. A semiconductor structure corresponding to the above-mentioned method is also disclosed.

Abstract: The present disclosure provides a semiconductor device, including a substrate having a seal ring region and a circuit region, a seal ring structure disposed over the seal ring region, a first passivation layer disposed over the seal ring structure, the first passivation layer having a first passivation layer aperture over the seal ring structure, and a metal pad disposed over the first passivation layer, the metal pad coupled to the seal ring structure through the first passivation layer aperture and having a metal pad aperture above the first passivation layer aperture. The device further includes a second passivation layer disposed over the metal pad, the second passivation layer having a second passivation layer aperture above the metal pad aperture, and a polyimide layer disposed over the second passivation layer, the polyimide layer filling the second passivation layer aperture to form a polyimide root at an exterior tapered edge of the polyimide layer.

Abstract: A multilayer structure comprises: a substrate; and, a plurality of polymerizable layers successively deposited on the substrate, with each successive layer having a greater dielectric polarizability than the preceding layer(s), so that each successive layer will absorb microwave energy preferentially to the preceding layer(s). In this way, successive layers can be cured without over-curing the preceding layers. The individual layers are preferably materials from a single chemical family (e.g., epoxies, polyimides, PBO, etc.) and have similar properties after curing. The dielectric polarizabilities may be adjusted by modifying such factors as chain endcap dipole strength, cross-linker dipole strength, promoter, solvent, and backbone type. The invention is particularly suitable for producing various polymer layers on silicon for electronic applications. An associated method is also disclosed.

Abstract: Some embodiments relate to an integrated circuit. The integrated circuit includes an inductive or capacitive wireless communication structure located on a die region of the integrated circuit. This wireless communication structure is configured to wirelessly receive a test stimulus vector to test circuitry on the die region. The integrated circuit also includes a landing region having a size and location suitable to allow a conductive needle or conductive probe to come into direct physical and electrical contact with the landing region. The landing region provides a DC power supply to the circuitry on the die region while the test stimulus vector is wirelessly received.

Abstract: A semiconductor integrated circuit device with a balun which is formed above a conductive semiconductor substrate and which includes a dielectric film, an unbalanced line for transmitting an unbalanced signal, and balanced lines for transmitting a balanced signal. The unbalanced line is placed opposite to the balanced lines via a nano-composite film that is a region of the dielectric film. The nano-composite film, interposed between the unbalanced line and the balanced lines, has a relative permittivity higher than that of other regions of the dielectric film. This allows suppression of electromagnetic coupling of transmission lines or passive elements other than the balun, thereby providing a semiconductor device with a wide-band and small-size balun.

Abstract: According to an embodiment of the invention, a passivation layer structure of a semiconductor device disposed on a semiconductor substrate is provided, which includes a passivation layer structure disposed on the semiconductor substrate, wherein the passivation layer structure includes a halogen-doped aluminum oxide layer. According to an embodiment of the invention, a method for forming a passivation structure of a semiconductor device is provided.

Abstract: A micro light emitting diode (LED) and a method of forming an array of micro LEDs for transfer to a receiving substrate are described. The micro LED structure may include a micro p-n diode and a metallization layer, with the metallization layer between the micro p-n diode and a bonding layer. A conformal dielectric barrier layer may span sidewalls of the micro p-n diode. The micro LED structure and micro LED array may be picked up and transferred to a receiving substrate.

Abstract: One embodiment of a method of processing a semiconductor wafer having a peripheral portion includes providing external support structure and restraining radially inward displacement of the wafer peripheral portion with the external support structure.

Abstract: This disclosure provides systems, processes, and apparatus implementing and using techniques for fabricating flexible integrated circuit (IC) device layers. In one implementation, a sacrificial layer is deposited on a substrate. The sacrificial layer can include amorphous silicon or molybdenum, by way of example. One or more electronic components are formed on the sacrificial layer. A polymer coating is provided on the one or more electronic components to define a coated device layer. The sacrificial layer is removed to release the coated device layer from the substrate. The sacrificial layer can be removed using a xenon difluoride gas or by etching, for example. Coated device layers made in accordance with this process can be stacked. The substrate can be formed of glass, silicon, a plastic, a ceramic, a compound semiconductor, and/or a metal, depending on the desired implementation. The electronic component(s) can include a passive component such as a resistor, an inductor, or a capacitor.

Abstract: A micro light emitting diode (LED) and a method of forming an array of micro LEDs for transfer to a receiving substrate are described. The micro LED structure may include a micro p-n diode and a metallization layer, with the metallization layer between the micro p-n diode and a bonding layer. A conformal dielectric barrier layer may span sidewalls of the micro p-n diode. The micro LED structure and micro LED array may be picked up and transferred to a receiving substrate.

Abstract: A method for manufacturing a semiconductor device is disclosed. The method includes forming a shallow trench isolation (STI) region extending in a first direction on a semiconductor substrate, forming a mask layer extending in a second direction that intersects with the first direction on the semiconductor substrate and forming a trench on the semiconductor substrate by using the STI region and the mask layer as masks. In addition, the method includes forming a charge storage layer so as to cover the trench and forming a conductive layer on side surfaces of the trench and the mask layer. Word lines are formed from the conductive layer on side surfaces of the trench that oppose in the first direction by etching. The word lines are separated from each other and extend in the second direction.

Abstract: The present disclosure provides a semiconductor device. The semiconductor device includes a substrate and an interconnect structure disposed over the substrate. The interconnect structure includes a plurality of interconnect layers. One of the interconnect layers contains: a plurality of metal via slots and a bulk metal component disposed over the plurality of metal via slots. The present disclosure also provides a method. The method includes providing a wafer, and forming a first layer over the wafer. The method includes forming an interconnect structure over the first layer. The forming the interconnect structure includes forming a second interconnect layer over the first layer, and forming a third interconnect layer over the second interconnect layer. The second interconnect layer is formed to contain a plurality of metal via slots and a bulk metal component formed over the plurality of metal via slots. The third interconnect layer contains one or more metal trenches.

Abstract: A mmWave electronics package constructed from common Printed Circuit Board (PCB) technology and a metal cover. Assembly of the package uses standard pick and place technology and heat is dissipated directly to a pad on the package. Input/output of mmWave signal(s) is achieved through a rectangular waveguide. Mounting of the electronic package to an electrical printed circuit board (PCB) is performed using conventional reflow soldering processes and includes a waveguide I/O connected to an mmWave antenna. The electronic package provides for transmission of low frequency, dc and ground signals from the semiconductor chip inside the package to the PCB it is mounted on. An impedance matching scheme matches the chip to high frequency board transition by altering the ground plane within the chip. A ground plane on the high frequency board encircles the high frequency signal bump to confine the electromagnetic fields to the bump region reducing radiation loss.

Abstract: The present application relates to a multiple component which is to be subsequently individualized by forming components containing active structures, in addition to a corresponding component which can be used in microsystem technology systems. The multiple component and/or component comprises a flat substrate and also a flat cap structure which are bound to each other such that they surround at least one first and one second cavity per component, which are sealed against each other and towards the outside. The first of the two cavities is provided with getter material and due to the getter material has a different internal pressure and/or a different gas composition than the second cavity. The present application also relates to a method for producing the type of component and/or components for which gas mixtures of various types of gas have a different absorption ratio in relation to the getter material.

Abstract: A semiconductor apparatus according to aspects of the invention can include a metal base; resin case having a bonding plane facing metal base; a coating groove formed in bonding plane and holding adhesive for bonding resin case to metal base at a predetermined position, with the top plane of the wall that forms coating groove being spaced apart from the plane which contains bonding plane such that an escape space is formed between the metal base and the resin case; the escape space receiving the excess amount of adhesive which has flowed out from the coating groove; and a receiver groove communicating to the escape space and receiving securely the excess amount of adhesive which the escape space has failed to receive. If an excess amount of adhesive too much for the receiver groove to receive is coated, the excess amount of adhesive can be received in a stopper groove.

Abstract: An apparatus and method for manufacturing a micro-electrical mechanical system (MEMS) package comprising a first molded body having a first acoustic port, a second molded body connected to the first molded body, a leadframe at least partially integral with at least one of the first and second molded bodies, a die cavity provided on at least one of the first and second molded bodies and having a second acoustic port, a MEMS die provided on the die cavity, a channel connecting the first and second acoustic ports, the first molded body sealing at least a portion of the channel, and a lid attached to the second molded body and sealing at least a portion of the die cavity.

Abstract: A die in accordance with various embodiments may include a metallization area located proximate an edge of the die, and an electrical connection connected to the metallization area and running from the metallization area to the edge, wherein the electrical connection is free from metal. A wafer in accordance with various embodiments may include a die region having a metallization area, a kerf region having an electric or electronic device, and an electrical connection connecting the electric or electronic device with the metallization area, wherein the electrical connection is free from metal.

Abstract: A semiconductor device includes: an insulating layer formed on a substrate; a plurality of interlayer insulating films which are formed on the insulating layer and comprise an opening window; a multilayer wiring which is formed with a plurality of wiring layers and a plurality of vias formed in the plurality of interlayer insulating films; a metal pad connected with the multilayer wiring, an upper surface part of the metal pad being a bottom part of the opening window, the metal pad formed closer to the substrate than a wiring layer of a lowermost layer of the plurality of wiring layers and is; and a pad ring provided on the metal pad, the pad ring penetrating the plurality of interlayer insulating films and the pad ring surrounding the opening window.

Abstract: A transmission line structure for semiconductor RF and wireless circuits, and method for forming the same. The transmission line structure includes embodiments having a first die including a first substrate, a first insulating layer, and a ground plane, and a second die including a second substrate, a second insulating layer, and a signal transmission line. The second die may be positioned above and spaced apart from the first die. An underfill is disposed between the ground plane of the first die and the signal transmission line of the second die. Collectively, the ground plane and transmission line of the first and second die and underfill forms a compact transmission line structure. In some embodiments, the transmission line structure may be used for microwave applications.

Abstract: A metal shield structure is provided for an integrated circuit (IC) having at least a first metal contact coupled to a fixed potential and a second metal contact. A first passivation layer is located between the first and second metal contacts and on a first portion of the first metal contact and a first portion of the second metal contact, leaving a second portion of the first metal contact and a second portion of the second metal contact uncovered by the first passivation layer. A metal shield layer is provided on the second portion of the first metal contact and on the first passivation layer, and a second passivation layer is formed on the metal shield layer.

Abstract: Disclosed herein are various electrical test structures for evaluating semiconductor devices that employ high-k dielectrics and/or metal gate electrode structures. In one example, the test structure disclosed herein includes a first resistor comprised of at least one of a high-k layer of insulating material or a metal layer and a silicon-containing material layer and first and second spaced-apart metal silicide regions formed on the silicon-containing material layer, wherein the silicon-containing layer further comprises a non-silicided region positioned between the first and second spaced-apart metal silicide regions.

Abstract: Electrical connections for chip scale packaging are disclosed. In one embodiment, a semiconductor device includes a post-passivation layer disposed over a substrate, the substrate having a first direction of coefficient of thermal expansion mismatch. The semiconductor device includes a first opening through the post-passivation layer, the first opening comprising a plurality of elongated apertures. A longest of the plurality of elongated apertures comprises a first dimension, wherein the first dimension is aligned substantially perpendicular to the first direction of coefficient of thermal expansion mismatch.

Abstract: In a laminated chip package, a plurality of semiconductor plates each having a semiconductor device and a wiring electrode connected to the semiconductor device are laminated. On a side surface for wiring of the laminated chip package, an end face of an inner electrode for examination formed inside the side surface for wiring in the semiconductor plate is formed. The laminated chip package further has an outer electrode for examination connecting the end faces of the inner electrodes for examination along a lamination direction of the semiconductor plates, only for two adjacent semiconductor plates among the semiconductor plates.

Abstract: An electrostatic discharge protection device is disclosed. The electrostatic discharge protection device preferably includes a first transistor, a second transistor, and an electrostatic discharge clamping circuit. The first transistor includes a first drain electrically connected to an input/output pin of a chip, a first source electrically connected to a first voltage input pin of the chip, and a first gate. The first drain is preferably an internally shrunk drain. The second transistor includes a second drain electrically connected to the input/output pin of the chip, a second source electrically connected to a second voltage input pin and a second gate. The electrostatic discharge clamping circuit is electrically connected to the first voltage input pin and the second voltage input pin.

Abstract: A ground layer of a multilayer wiring board includes: a first clearance through which a first differential via is inserted without coming into contact with the ground layer; and a second clearance through which a second differential via is inserted without coming into contact with the ground layer. A distance between an outer edge of the first clearance on the side of the second differential via and the first differential via is set shorter than a distance between an outer edge of the first clearance on the side opposite from the second differential via and the first differential via. A distance between an outer edge of the second clearance on the side of the first differential via and the second differential via is set shorter than a distance between an outer edge of the second clearance on the side opposite from the first differential via and the second differential via.

Abstract: The present invention discloses methods and apparatuses for the separations of IC fabrication and assembling of separated IC components to form complete IC structures. In an embodiment, the present fabrication separation of an IC structure into multiple discrete components can take advantages of dedicated IC fabrication facilities and achieve more cost effective products. In another embodiment, the present chip assembling provides high density interconnect wires between bond pads, enabling cost-effective assembling of small chip components. In an aspect, the present process provides a beveled slope of the components to facilitate interconnection bonding.

Abstract: In a method of improving bump allocation for a semiconductor device and a semiconductor device with improved bump allocation, a predetermined signal bump is surrounded with at least three bumps, each being a ground bump or a paired differential signal bump.

Abstract: A seal ring structure is formed through a multilayer structure of a plurality of dielectric films in a peripheral part of a chip region to surround the chip region. A dual damascene interconnect in which an interconnect and a plug connected to the interconnect are integrated is formed in at least one of the dielectric films in the chip region. Part of the seal ring structure formed in the dielectric film in which the dual damascene interconnect is formed is continuous. A protection film formed on the multilayer structure has an opening on the seal ring. A cap layer connected to the seal ring is formed in the opening.