Abstract: A gate drive circuit includes a shift register having stages connected to each other in series. An (m)-th stage (‘m’ is a natural number) includes an output part, a discharging part, a first holding part and a second holding part. The output part outputs the first clock signal as a gate signal in response to a first clock signal provided from an external device and discharges the gate signal in response to a second input signal. The output part includes a first transistor having a first channel length. The discharging part discharges a signal of the first node to the second voltage level. The first holding part maintains a signal of the first node at a level of the gate signal, and is discharged to the second voltage level. The first holding part includes a second transistor having a second channel length that is longer than the first channel length. The second holding part maintains a signal of the first node at a level of the second voltage level.

Abstract: A passivation structure and fabricating method thereof includes providing a chip having a main die region and a scribe line region defined thereon and a plurality of metal pads respectively positioned in the main die region and the scribe line region, forming a first patterned passivation layer having a plurality of first openings and second openings respectively exposing the metal pads in the main die region and the scribe line region on the chip, and forming a second patterned passivation layer filling the first openings in the scribe line region and having a plurality of third openings corresponding to the first openings thus exposing the metal pads in the main die region.

Abstract: One of the simplest forms of data storage devices is the diode array storage device. However, a problem with diode array storage devices is that as the size of the array increases, the number of non-addressed diodes connected between a given selected row or column of the array and the non-addressed columns or rows of the array, respectively, also becomes very large. While the leakage current through any one non-addressed diode on the selected row or column will have little impact on the operation of the device, the cumulative leakage through multiple thousands of non-addressed diodes can become significant. This aggregate leakage current can become great enough that the output voltage can be shifted such that the threshold for distinguishing between a one state and a zero state of the addressed diode location can become obscured and can result in a misreading of the addressed diode location. The present invention is a means to manage the leakage currents in a diode array storage device.

Abstract: A method of programming a carbon nanotube memory cell is provided, wherein the memory cell comprises a first conductor, a steering element, a carbon nanotube fabric, and a second conductor, wherein the steering element and the carbon nanotube fabric are arranged electrically in series between the first conductor and the second conductor, and wherein the entire carbon nanotube memory cell is formed above a substrate, the carbon nanotube fabric having a first resistivity, the method including applying a first electrical set pulse between the first conductor and the second conductor, wherein, after application of the first electrical set pulse, the carbon nanotube fabric has a second resistivity, the second resistivity less than the first resistivity. Other aspects are also provided.

Abstract: Wafer-level chip scale (WLCSP) semiconductor packages and methods for making and using the same are described. The WLCSP semiconductor packages contain a grid array of land pads rather than solder balls or solder bumps. The land pads can be provided directly on a semiconductor wafer by using a leadframe interconnect structure that has been formed from a leadframe. The land pads can be used to mount the WLCSP to a circuit board. Such a configuration allows the formation of a thinner chip scale semiconductor package using a simpler manufacturing process, thereby reducing costs and improving performance. Other embodiments are described.

Abstract: Provided is a semiconductor device comprising: a plurality of bit line patterns; a plurality of pad patterns that are respectively connected to the plurality of bit line patterns; and at least one contact that is formed on each of the plurality of pad patterns, wherein the pitch of the plurality of pad patterns is greater than the pitch of the plurality of bit line patterns. The bit line patterns may be formed using a double patterning technology (DPT).

Abstract: The invention provides a semiconductor device and a method for fabricating the same capable of preventing a field plate portion from being delaminated from an insulating film by stress inherent in a semiconductor layer even if the stress is released in forming a trench in part of the semiconductor layer where the semiconductor device is to be separated and capable of having a higher breakdown property of the semiconductor device. The semiconductor device has source, drain and gate electrodes, insulating films that insulate the electrodes on an electron supplying layer and a mesa-structure formed at part where the semiconductor device is to be separated. The gate electrode has a first electrode layer having a function of the electrode and a second electrode layer having a field plate portion whose part that contacts with the insulating film is made of a metallic material that adheres well to the insulating film.

Abstract: In a memory device and a method of forming the same, in one embodiment, the memory device comprises a first word line structure on a substrate, the first word line structure extending in a first direction. A bit line is provided over the first word line structure and spaced apart from the first word line by a first gap, the bit line extending in a second direction transverse to the first direction. A second word line structure is provided over the bit line and spaced apart from the bit line by a second gap, the second word line structure extending in the first direction.

Abstract: One embodiment relates to an integrated circuit that includes a memory array of pillars arranged in rows and columns. The pillars are separated from one another by row trenches and column trenches. The column trenches include a pair of parallel column trenches. A first trench of the pair includes two parallel bit lines coupled to pillars adjacent to the first trench. A second trench of the pair is free of bit lines. Other methods, devices, and systems are also disclosed.

Abstract: A memory cell array including a data line; a capacitor; and a transistor coupled between the data line and the capacitor. At least one of the capacitor and the transistor includes a material with a mutable electrical characteristic. A memory cell array including a first transistor coupled between a first node, a second node, and a third node; and a second transistor coupled between the second node and a fourth node. The first transistor includes a material with a mutable electrical characteristic.

Abstract: An array of memory cells is disclosed. The memory cell includes a fuse and at least one transistor. The transistor is used to control the programming or sensing of the fuse. A program voltage is applied to a stack of first and second conductive layers. A first portion of the stack couples the program voltage to a terminal of the transistor in a cell. A second portion of the stack couples the program voltage to a terminal of the transistor in another cell.

Abstract: A symmetrical circuit is disclosed (FIG. 4). The circuit includes a first transistor (220) having a first channel in a substantial shape of a parallelogram (FIG. 5A) with acute angles. The first transistor has a first current path (506) oriented in a first crystal direction (520). A first control gate (362) overlies the first channel. A second transistor (222) is connected to the first transistor and has a second channel in the substantial shape of a parallelogram with acute angles. The second transistor has a second current path (502) oriented parallel to the first current path. A second control gate (360) overlies the second channel.

Abstract: Carbon nanotube template arrays may be edited to form connections between proximate nanotubes and/or to delete undesired nanotubes or nanotube junctions.

Abstract: A semiconductor memory device comprises a semiconductor substrate; a cell array block formed on the semiconductor substrate and including plural stacked cell array layers each comprising a plurality of first lines, a plurality of second lines crossing the plurality of first lines, and memory cells connected at intersections of the first and second lines between both lines; and a plurality of contact plugs extending in the stack direction of the cell array layers to connect between the first lines, between the second lines, between the first or second line and the semiconductor substrate, or between the first or second line and another metal line, in the cell array layers. The first or second line in a certain one of the cell array layers has a contact connector making contact with both sides of the contact plug.

Abstract: A rescue structure to repair an open wire includes a first metal layer having at least a rescue line, an isolation layer formed on the first metal layer, and a second metal layer formed on the isolation layer. The second metal layer has at least a signal line crossing the rescue line to form an enlarged intersection node. The intersection node is particularly arranged far from the side where the rescue line is used for signal transmission.

Abstract: The invention is directed to an improved semiconductor chip that reduces crack initiation and propagation into the active area of a semiconductor chip. A semiconductor wafer includes dicing channels that separate semiconductor chips and holes through a portion of a semiconductor chip, which are located at the intersection of the dicing channels. Once diced from the semiconductor wafer, semiconductor chips are created without ninety degree angle corners.

Abstract: A cross point memory cell includes a portion of a first distributed diode, a portion of a second distributed diode, a memory layer located between the portion of the first distributed diode and the portion of a second distributed diode, a bit line electrically connected to the first distributed diode, and a word line electrically connected to the second distributed diode.

Abstract: A GaN-based thin film (thick film) is grown using a metal buffer layer grown on a substrate. (a) A metal buffer layer (210) made of, for example, Cr or Cu is vapor-deposited on a sapphire substrate (120). (b) A substrate obtained by vapor-depositing the metal buffer layer (210) on the sapphire substrate (120) is nitrided in an ammonia gas ambient, thereby forming a metal nitride layer (212). (c) A GaN buffer layer (222) is grown on the nitrided metal buffer layers (210, 212). (d) Finally, a GaN single-crystal layer (220) is grown. This GaN single-crystal layer (220) can be grown to have various thicknesses depending on the objects. A freestanding substrate can be fabricated by selective chemical etching of the substrate fabricated by the above steps. It is also possible to use the substrate fabricated by the above steps as a GaN template substrate for fabricating a GaN-based light emitting diode or laser diode.

Abstract: A laser beam machining method for a wafer, wherein an operation of irradiating the inside of a wafer with a laser beam L along each of planned dividing lines is repeated a plural number of times from a position proximate to a back-side surface of the wafer toward a face-side surface of the wafer so that a plurality of composite layers each including a denatured layer and a cracked layer extending from the denatured layer toward the face-side surface are formed stepwise at intervals (first laser beam irradiation step). Subsequently, each of some of non-cracked layers between the composite layers is irradiated with the laser beam L so as to extend the cracked layer of a given one of the composite layers and to cause the cracked layer to reach the denatured layer of the composite layer which is adjacent to the given one composite layer. The denatured layers and the cracked layers which are sufficient for enabling the wafer to be split are formed by a reduced number of laser beam irradiation operations.

Abstract: A conductor carrier provides, separately manufactured, conductive pathways, on a wafer level, which may be coupled to a wafer of fully fabricated integrated circuits. Such conductor carriers include an insulating body having two major surfaces with conductors disposed on each of those surfaces, and conductors disposed within the insulating body so as to provide signal continuity between various conductors on each of the two surfaces. An assembly can be formed by permanently or removably attaching the conductor carrier to the wafer. Conductor carriers may include an evacuation pathway suitable for removing air, or other gases, from between the conductor and the wafer so as to create a pressure differential that urges the conductor carrier into contact with the wafer. Conductor carriers may include a groove which is suitable for receiving a sealing ring; and may include a street map which is suitable for providing guidance to a wafer sawing operation.

Abstract: A capacitor-cell is in an integrated circuit that is configured by disposing a plurality of cells on a site that is on a chip and that is provided between a power line and a grounding line in a direction of the power line and grounding line. The capacitor cell is disposed in a remaining region on the site, after the plurality of cells are disposed on the site. The capacitor-cell includes a gate poly for accumulating capacitance extending up to at least one of positions of the power line and the grounding line in a planar quadrangular cell-frame that is set for disposing the plurality of cells on the site.

Abstract: Electronic apparatus, methods of forming the electronic apparatus, and methods of operating the electronic apparatus include a read only memory having a memory array of bit-lines, where the bit-lines are arranged such that each bit-line has a shared arrangement with one or more other bit-lines of the memory array. Each shared arrangement is structured to operably store a plurality of bits.

Abstract: One embodiment of the invention is a semiconductor system (1400) of arrays (1401, 1402, etc.) of packaged devices. Each array includes a sheet-like substrate (1411, 1412, etc.) made of insulating material integral with conductive horizontal lines and vertical vias, and terminals on the surfaces. Semiconductor components, which may include more than one active or passive chips, or chips of different sizes, are attached to the substrate; the electrical connections may include flip-chip, wire bond, or combination techniques. Encapsulation compound (1412, 1422, etc.), which adheres to the substrate, embeds the connected components. Metal posts (1431, 1432, etc.) traverse the encapsulation compound vertically, connecting the substrate vias with pads on the encapsulation surface. The pads are covered with solder bodies used to connect to the next-level device array so that a 3-dimensional system of packaged devices is formed.

Abstract: A circuit for a nonvolatile memory cell can include a charge-altering terminal and an output terminal. The circuit can also include a first transistor having a gate electrode that electrically floats and an active region including a current-carrying electrode, wherein the current-carrying electrode is coupled to the output terminal. The circuit can further include a second transistor having a first electrode and a second electrode, wherein the first electrode is coupled to the gate electrode of the first transistor, and the second electrode is coupled to the charge-altering terminal. When changing the state of the memory cell, the second transistor can be active and no significant amount of charge carriers are transferred between the gate electrode of the first transistor and the active region of the first transistor. Other embodiments can include the electronic device itself and a process of forming the electronic device.

Abstract: Programmable devices, methods of manufacture thereof, and methods of programming devices are disclosed. In one embodiment, a programmable device includes a link and at least one first contact coupled to a first end of the link. The at least one first contact is adjacent a portion of a top surface of the link and at least one sidewall of the link. The programmable device includes at least one second contact coupled to a second end of the link. The at least one second contact is adjacent a portion of the top surface of the link and at least one sidewall of the link.

Abstract: Electromechanical circuits, such as memory cells, and methods for making same are disclosed. The circuits include a structure having electrically conductive traces and supports extending from a surface of the substrate, and nanotube ribbons suspended by the supports that cross the electrically conductive traces, wherein each ribbon comprises one or more nanotubes. The electro-mechanical circuit elements are made by providing a structure having electrically conductive traces and supports, in which the supports extend from a surface of the substrate. A layer of nanotubes is provided over the supports, and portions of the layer of nanotubes are selectively removed to form ribbons of nanotubes that cross the electrically conductive traces. Each ribbon includes one or more nanotubes.

Abstract: A semiconductor integrated circuit device includes a first component, a second component, a plurality of first, second and third contacts, and a plurality of signal lines having a plurality of first wires, and connecting the first and second component, each of the first wires having a first, second, third and fourth part, each of the parts having a resistivity, the second part having a first resistivity, a different value of the first resistance being set for each of the plurality of first wires, the first, third and fourth parts having a second or third resistivity which is lower than the first resistivity, the first and second part being electrically connected in series by the first contact, the second and third part being electrically connected in series by the second contact, and the third and fourth part being electrically connected in series by the third contact.

Abstract: An integrated circuit including an array of low resistive vertical diodes and method. One embodiment provides an array of diodes at least partially formed in a substrate for selecting one of a plurality of memory cells. A diode is coupled to a word line. The word line includes a straight-lined portion and protrusions. The diode includes an active area located between two adjacent protrusions.

Abstract: The invention provides for polysilicon vias connecting conductive polysilicon layers formed at different heights. Polysilicon vias are advantageously used in a monolithic three dimensional memory array of charge storage transistors. Polysilicon vias according to the present invention can be used, for example, to connect the channel layer of a first device level of charge storage transistor memory cells to the channel layer of a second device layer of such cells formed above the first device level. Similarly, vias according to the present invention can be used to connect the wordline of a first device level of charge storage transistor memory cells to the channel layer of a second device layer of such cells.

Abstract: A wafer laser processing method for forming grooves along streets by applying a pulse laser beam along the streets for sectioning a plurality of devices of a wafer having the plurality of devices which are composed of a laminate consisting of an insulating film and a functional film, on the front surface of a substrate, wherein the pulse laser beam is set to have a repetition frequency of 150 kHz to 100 MHz and an energy per unit length of 5 to 25 J/m.

Abstract: A one time programmable memory cell having an anti-fuse device with a low threshold voltage independent of core circuit process manufacturing technology is presented. A two transistor memory cell having a pass transistor and an anti-fuse device, or a single transistor memory cell having a dual thickness gate oxide, are formed in a high voltage well that is formed for high voltage transistors. The threshold voltage of the anti-fuse device differs from the threshold voltages of any transistor in the core circuits of the memory device, but has a gate oxide thickness that is the same as a transistor in the core circuits. The pass transistor has a threshold voltage that differs from the threshold voltages of any transistor in the core circuits, and has a gate oxide thickness that differs from any transistor in the core circuits.

Abstract: Disclosed are embodiments of an improved integrated circuit switching device that incorporates multiple sets of series connected field effect transistors with each set further connected in parallel between two nodes. The sets are arranged in a linear fashion with each set positioned such that it is in contact with and essentially symmetrical relative to an adjacent set. Arranging the sets in this manner allows adjacent diffusion regions of the same type (i.e., sources or drains) from adjacent sets to be merged. Merging of the diffusion regions provides several benefits, including but not limited to, reducing the device size, reducing the amount of required wiring for the device (i.e., reducing resistance) and reducing side capacitance between the now merged diffusion regions and the substrate. Also disclosed are embodiments of an associated design structure for the device and an associated method of forming the device.

Abstract: A method for manufacturing an integrated circuit and an integrated circuit are described. In one embodiment, the method for manufacturing the integrated circuit includes determining a layout for numerous memory elements based on memory-specific parameters, and determining a layout for a front-end-of-line (FEOL) component of the integrated circuit based on electrical parameters. Once these two layouts are determined, the layouts are combined to produce a layout for a memory cell on the integrated circuit.

Abstract: A semiconductor device includes a base plate, at least one first conductive layer carried by the base plate, and a semiconductor constructing body formed on or above the base plate, and having a semiconductor substrate and a plurality of external connecting electrodes formed on the semiconductor substrate. An insulating layer is formed on the base plate around the semiconductor constructing body. A plurality of second conductive layers are formed on the insulating layer and electrically connected to the external connecting electrodes of the semiconductor constructing body. A vertical conducting portion is formed on side surfaces of the insulating film and base plate, and electrically connects the first conductive layer and at least one of the second conductive layers.

Abstract: A semiconductor device has a plurality of insulated gate field effect transistors on a semiconductor substrate. A SAC contact hole is formed between two gates of the insulated gate field effect transistors. A side portion of the SAC contact hole is separated from two gates of the insulated gate field effect transistors by a side wall dielectric film and a dielectric film. A polycrystalline silicon plug having a U-shaped section structure is formed in a bottom portion of the SAC contact hole. A barrier metal film is formed on the polycrystalline silicon plug. A metal plug is buried on the barrier metal film so that covering on the SAC contact hole.

Abstract: Provided is a semiconductor package and method of manufacturing same. The method includes: forming a plurality of semiconductor chips which have the same pattern direction on a semiconductor substrate, each of which includes a memory cell region, a peripheral region and a pad region, and in each of which the pad region is disposed in an edge region; separating the semiconductor chips, which are formed on the semiconductor substrate, from one another; and disposing semiconductor chips, which are selected from the separated semiconductor chips, on a package substrate by changing the pattern directions of the selected semiconductor chips and arranging pad regions of the selected semiconductor chips in a center region of the package substrate.

Abstract: A surface emitting semiconductor laser device comprising at least one surface emitting semiconductor laser (21) having a vertical emitter (1) and at least one pump radiation source (2), which are monolithically integrated alongside one another onto a common substrate (13), is described. The semiconductor laser device additionally has a heat-conducting element (18), which is in thermal contact with the semiconductor laser (21) and has a mounting area provided for mounting on a carrier (27). Methods for producing such a surface emitting semiconductor laser device are furthermore described.

Abstract: An integrated metal-insulator-metal capacitor is formed so that there is an extension portion of its top plate that does not face any portion of the bottom plate, and an extension portion of its bottom plate that does not face any portion of the top plate. Vias connecting the MIM capacitor plates to conductors in an overlying metallization layer are formed so as to contact the extension portions of the top and bottom plates. Etching of the via holes is simplified because it is permissible for the via holes to punch through the extension portions of the capacitor plates. The bottom plate of the MIM capacitor is inlaid. The top plate of the MIM capacitor may be inlaid.

Abstract: Semiconductor devices, methods of manufacturing thereof, and methods of arranging circuit components of an integrated circuit are disclosed. In one embodiment, a semiconductor device includes an array of a plurality of devices arranged in a plurality of rows. At least one electrostatic discharge (ESD) protection circuit or a portion thereof is disposed in at least one of the plurality of rows of the array of the plurality of devices.

Abstract: Variable-resistance memory material cells are contacted by vertical bottom spacer electrodes. Variable-resistance material memory spacer cells are contacted along the edge by electrodes. Processes include the formation of the bottom spacer electrodes as well as the variable-resistance material memory spacer cells. Devices include the variable-resistance memory cells.

Abstract: A semiconductor device and methods of forming same are disclosed having multiple die redistribution layer. After fabrication of semiconductor die on a wafer and prior to singulation from the wafer, adjacent semiconductor die are paired together and a redistribution layer may be formed across the die pair. The redistribution layer may be used to redistribute at least a portion of the bond pads from the first die in the pair to a second die in the pair. One die in each pair will be a working die and the other die in each pair will be a dummy die. The function of the integrated circuit beneath the redistribution layer on the dummy die is at least partially sacrificed.

Abstract: A nonvolatile memory cell includes a gate controlled diode steering element and a resistivity switching element.

Abstract: Devices and methods are disclosed for logic gate devices to provide reduced leakage while improving performance. The device is configured for low leakage logic application where high threshold voltage devices are used to reduce leakage at the expense of reduced logic speed. Better performance is achieved than a high threshold voltage stack.

Abstract: The use of atomic layer deposition (ALD) to form a dielectric layer of hafnium oxide (HfO2) doped with dysprosium (Dy) and a method of fabricating such a combination gate and dielectric layer produces a reliable structure for use in a variety of electronic devices. Forming the dielectric structure includes depositing hafnium oxide using atomic layer deposition onto a substrate surface using precursor chemicals, followed by depositing dysprosium oxide onto the substrate using precursor chemicals, and repeating to form the thin laminate structure.

Abstract: Memory arrays can be implemented including word lines connected to memory transistors and corresponding select transistors. Each memory transistor is also connected to an array select transistor. Each select transistor is also connected to a bit line. The memory transistors are arranged such that they define bytes of data. A well line is connected to each portion of the semiconductor substrate that defines an array of bytes.

Abstract: A method for cutting a liquid crystal display panel including: forming prearranged cut lines on a pair of attached mother substrates on which a plurality of panel regions have been disposed; and separating the liquid crystal display panel from a dummy glass around the liquid crystal display panel through a transfer unit which includes a body for adsorbing a liquid crystal display panel and transferring it, and a plate attached on an edge of the body, fixing and separating a dummy glass of a mother substrate from the liquid crystal display panel, and moving up and down separately from the body. A dummy removing plate is attached at an edge of a trans hand to remove a dummy glass when a breaking process-finished liquid crystal display panel is extracted, so a damage of the liquid crystal display panel due to the dummy glass can be prevented.

Abstract: A multi-chip package includes a package substrate. First and second semiconductor die are formed on the package substrate. The first and the second semiconductor die are configured to communicate with each other via a high-speed serial communications protocol.

Abstract: Carbon nanotube template arrays may be edited to form connections between proximate nanotubes and/or to delete undesired nanotubes or nanotube junctions.

Abstract: Methods of processing a semiconductor structure including a metal layer in the presence of organic material include flowing an aqueous mixture including an oxidizing agent over the semiconductor structure during processing of the semiconductor structure. Processing the semiconductor structure may include sawing the semiconductor structure and/or scrubbing the semiconductor structure with pressurized water. The oxidizing agent may include a peroxide, such as hydrogen peroxide, or another oxidizing agent.

Abstract: A memory device can be implemented including word lines connected to an array of memory transistors. Each memory transistor is also connected to bit lines and a select transistor. The select transistors each have their sources connected to a conductive source line, by a shunt and the gate of each select transistor is connected to a select line.