Abstract: The present invention provides a semiconductor device which includes a gate electrode shaped in the form of an approximately quadrangular prism, including a laminated body of a gate oxide layer, a gate polysilicon layer and a gate silicon nitride layer provided in a first conduction type substrate, a second conduction type implantation region provided in a region outside the gate electrode, a sidewall that exposes a top face of the gate electrode and is formed by laminating a sidewall mask oxide layer covering side surfaces, an electron storage nitride layer and a sidewall silicon oxide layer, and a source/drain diffusion layer provided in the first conduction type substrate exposed from the gate electrode and the sidewall.

Abstract: A method for forming a semiconductor device includes forming a first dielectric layer over a first portion of a substrate, forming a charge storage layer over the first dielectric layer and etching a trench in the charge storage layer and the first dielectric layer, where the trench extends to the substrate. The method also includes implanting n-type impurities into the substrate to form an n-type region having a first depth and a first width and implanting p-type impurities into the substrate after implanting the n-type impurities, the p-type impurities forming a p-type region having a second depth and a second width. The method further includes forming a second dielectric layer over the charge storage layer and forming a control gate over the second dielectric layer.

Abstract: A method for forming a capacitor comprises providing a substrate. A bottom electrode material layer is formed on the substrate. A first mask layer is formed on the bottom electrode material layer. A second mask layer is formed on the first mask layer. The second mask layer is patterned to form a patterned second mask layer in a predetermined region for formation of a capacitor. A plurality of hemispherical grain structures are formed on a sidewall of the patterned second mask layer. The first mask layer is etched by using the hemispherical grain structures and the patterned second mask layer as a mask, thereby forming a patterned first mask layer having a pattern. The pattern of the first mask layer is transferred to the bottom electrode material layer. And, a capacitor dielectric layer and a top electrode layer are formed on the bottom electrode material layer to form the capacitor.

Abstract: A semiconductor memory device includes a semiconductor substrate. An inter-layer dielectric is disposed on the semiconductor substrate. A bit line is disposed on the inter-layer dielectric. A bit line spacer is fabricated of a nitride layer containing boron and/or carbon and covers sidewalls of the bit line. A method of fabricating the semiconductor memory device is also provided.

Abstract: Semiconductor devices with an improved overlay margin and methods of manufacturing the same are provided. In one aspect, a method includes forming a buried bit line in a substrate; forming an isolation layer in the substrate to define an active region, the isolation layer being parallel to the bit line without overlapping the bit line; and forming a gate line including a gate pattern and a conductive line by forming the gate pattern in the active region and forming a conductive line that extends at a right angle to the bit line across the active region and is electrically connected to the gate pattern disposed thereunder. The gate pattern and the conductive line can be integrally formed.

Abstract: An embodiment of the present invention is method of forming an array of 2 transistor DRAM cells organized in rows and columns in which the rows represent words and columns represent bits of the words, each bit column having a pair of balanced, true and complement bit lines, the bit lines being connected in a hierarchical bit line structure, comprising at least one local bit line pair and one global bit line pair, a sensing circuit connected to the global bit line pair detects a differential voltage transition on either line during a read access and provides a sensing strobe signal.

Abstract: A semiconductor memory device capable of preventing bridge formations in a peripheral circuit region includes: a cell region; a peripheral circuit region adjacent to the cell region; and a plurality of line patterns formed in the cell region and the peripheral circuit region, wherein a spacing distance between the line patterns is at least onefold greater than a width of the line pattern.

Abstract: In general, in one aspect, a method includes forming a spacer layer over a substrate having patterned stacks formed therein and trenches between the patterned stacks. A sacrificial polysilicon layer is deposited over the substrate to fill the trenches. A patterning layer is deposited over the substrate and patterned to define contact regions over at least a portion of the trenches. The sacrificial polysilicon layer is etched using the patterned patterning layer to form open regions.

Abstract: A metal/semiconductor/metal (MSM) binary switch memory device and fabrication process are provided. The device includes a memory resistor bottom electrode, a memory resistor material over the memory resistor bottom electrode, and a memory resistor top electrode over the memory resistor material. An MSM bottom electrode overlies the memory resistor top electrode, a semiconductor layer overlies the MSM bottom electrode, and an MSM top electrode overlies the semiconductor layer. The MSM bottom electrode can be a material such as Pt, Ir, Au, Ag, TiN, or Ti. The MSM top electrode can be a material such as Pt, Ir, Au, TiN, Ti, or Al. The semiconductor layer can be amorphous Si, ZnO2, or InO2.

Abstract: Disclosed herein is a method for fabricating a semiconductor memory device that can prevent oxidation of bit lines when forming an interlayer dielectric for isolating the bit lines. The bit line is formed on a semiconductor substrate where an underlying structure is formed. A silicon on dielectric (SOD) layer is formed on the resulting structure where the bit line is formed. A heat treatment can be performed on the SOD layer with a partial pressure ratio of water vapor (H2O) to hydrogen (H2) in a range of about 1×10?11 to about 1.55 at a temperature in a range of about 600° C. to about 1,100° C.

Abstract: A method of forming a micro pattern in a semiconductor device is disclosed. An oxide film mask is divided into a cell oxide film mask and a peri oxide film mask. Therefore, a connection between the cell and the peri region can be facilitated. A portion of a top surface of a first oxide film pattern between a region in which a word line will be formed and a region in which a select source line will be formed is removed. Accordingly, the space can be increased and program disturbance in the region in which the word line will be formed can be prevented. Furthermore, a pattern having a line of 50 nm and a space of 100 nm or a pattern having a line of 100 nm and a space of 50 nm, which exceeds the limitation of the ArF exposure equipment, can be formed using a pattern, which has a line of 100 nm and a space of 200 nm and therefore has a good process margin and a good critical dimension regularity.

Abstract: A method of forming word lines of a memory includes providing a substrate and forming a conductive layer on the substrate. A metal silicide layer is formed on the conductive layer, and a mask pattern is formed on the metal silicide layer. A mask liner covering the mask pattern and the surface of the metal silicide layer is formed on the substrate to shorten distances between the word line regions. An etching process is performed on the mask liner and the mask pattern until the partial surface of the metal silicide layer is exposed. The metal silicide layer and the conductive layer are etched to form word lines by utilizing the mask liner and the mask pattern as a mask. A silicon content of the metal silicide layer must be less than or equal to 2 for reducing a bridge failure rate between the word lines.

Abstract: A thin film array panel is provided, which includes: a gate line formed on a substrate; a first insulating layer formed on the gate line; a semiconductor layer formed on the gate insulating layer; a data line formed on the gate insulating layer and intersecting the gate line; a drain electrode formed at least on the semiconductor layer; a conductor arranged in parallel to the data line; a second insulating layer formed on the data line, the drain electrode, and the conductor and having a first contact hole exposing a portion of the drain electrode; and a pixel electrode formed on the second insulating layer, connected to the drain electrode through the first contact hole, fully covering the data line.

Abstract: A method is provided for forming a metal/semiconductor/metal (MSM) back-to-back Schottky diode from a silicon (Si) semiconductor. The method deposits a Si semiconductor layer between a bottom electrode and a top electrode, and forms a MSM diode having a threshold voltage, breakdown voltage, and on/off current ratio. The method is able to modify the threshold voltage, breakdown voltage, and on/off current ratio of the MSM diode in response to controlling the Si semiconductor layer thickness. Generally, both the threshold and breakdown voltage are increased in response to increasing the Si thickness. With respect to the on/off current ratio, there is an optimal thickness. The method is able to form an amorphous Si (a-Si) and polycrystalline Si (polySi) semiconductor layer using either chemical vapor deposition (CVD) or DC sputtering. The Si semiconductor can be doped with a Group V donor material, which decreases the threshold voltage and increases the breakdown voltage.

Abstract: A method for performing a bit line implant is disclosed. The method includes forming a group of structures on an oxide-nitride-oxide stack of a semiconductor device. Each structure of the group of structures includes a polysilicon portion and a hard mask portion. A first structure of the group of structures is separated from a second structure of the group of structures by less than 100 nanometers. The method further includes using the first structure and the second structure to isolate a portion of the semiconductor device for the bit line implant.

Abstract: Semiconductor devices with an improved overlay margin and methods of manufacturing the same are provided. In one aspect, a method includes forming a buried bit line in a substrate; forming an isolation layer in the substrate to define an active region, the isolation layer being parallel to the bit line without overlapping the bit line; and forming a gate line including a gate pattern and a conductive line by forming the gate pattern in the active region and forming a conductive line that extends at a right angle to the bit line across the active region and is electrically connected to the gate pattern disposed thereunder. The gate pattern and the conductive line can be integrally formed.

Abstract: A method for manufacturing a semiconductor device includes forming a second storage node contact hole with a mask for storage node and securing an overlay margin between a storage node contact hole and a storage node with a hard mask layer that serves as a hard mask as well as an anti-reflection film to reduce contact resistance, prevent reduction of a line-width of a lower interlayer insulating film and eliminate processes for depositing the interlayer insulating film and a polysilicon layer and etching the polysilicon layer to reduce a production period and cost of products.

Abstract: The invention includes memory arrays, and methods which can be utilized for forming memory arrays. A patterned etch stop can be used during memory array fabrication, with the etch stop covering storage node contact locations while leaving openings to bitline contact locations. An insulative material can be formed over the etch stop and over the bitline contact locations, and trenches can be formed through the insulative material. Conductive material can be provided within the trenches to form bitline interconnect lines which are in electrical contact with the bitline contact locations, and which are electrically isolated from the storage node contact locations by the etch stop. In subsequent processing, openings can be formed through the etch stop to the storage node contact locations. Memory storage devices can then be formed within the openings and in electrical contact with the storage node contact locations.

Abstract: A memory device includes isolation trenches that are formed generally parallel to and along associated strips of active area. A conductive bit line is recessed within each isolation trench such that the uppermost surface of the bit line is recessed below the uppermost surface of the base substrate. A bit line contact strap electrically couples the bit line to the active area both along a vertical dimension of the bit line strap and along a horizontal dimension across the uppermost surface of the base substrate.

Abstract: A semiconductor memory device includes a semiconductor substrate having an active region therein, an insulating layer on the substrate, and a lower electrode conductive pad extending through the insulating layer. The lower electrode conductive pad electrically contacts the active region at a lower surface of the lower electrode conductive pad. A lower electrode conductive plug on at least a portion of the lower electrode conductive pad electrically contacts the lower electrode conductive pad at an upper surface and at one sidewall thereof. The semiconductor device may further include a bitline conductor on the substrate adjacent the lower electrode conductive plug and an insulating spacer on a sidewall of the bitline conductor adjacent the lower electrode conductive plug. The insulating spacer may separate the lower electrode conductive plug from the bitline conductor by a distance sufficient to prevent electrical contact therebetween. Related methods are also discussed.

Abstract: Memory devices, arrays, and strings are described that facilitate the use of NROM memory cells in NAND architecture memory strings, arrays, and devices. NROM NAND architecture memory embodiments of the present invention include NROM memory cells in high density vertical NAND architecture arrays or strings facilitating the use of reduced feature size process techniques. These NAND architecture vertical NROM memory cell strings allow for an improved high density memory devices or arrays that can take advantage of the feature sizes semiconductor fabrication processes are generally capable of and yet do not suffer from charge separation issues in multi-bit NROM cells.

Abstract: A method for fabricating a semiconductor device includes forming a first trench by etching a substrate already provided with a storage node contact (SNC) region and a bit line contact (BLC) region, forming a protection layer on sidewalls of the first trench, forming a sacrificial layer over the substrate and filling the first trench, etching the sacrificial layer to have a portion of the sacrificial layer remain in the first trench in the BLC region of the substrate, forming a second trench extending horizontally by etching the substrate underneath the first trench, and filling the first and second trenches to form an isolation structure.

Abstract: The present invention has an object to provide a semiconductor device, an ID tag, in which delay of signal transmission with conductive layers is controlled. In addition, the other object is that a design method of such a semiconductor device is provided. A semiconductor device of the invention comprises a plurality of conductive layers, a plurality of first element groups each of which selects one among the conductive layers and a plurality of second element groups each of which amplifies a signal each transmitted from the conductive layers. Each of the second element groups is disposed between the first element groups. Stated another way, the first element group and the second element group are disposed alternately. The delay of the signal transmission with the plurality of conductive layers is controlled because a load by a parasitic capacitance is reduced due to the above feature.

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

Abstract: A metal/semiconductor/metal (MSM) binary switch memory device and fabrication process are provided. The device includes a memory resistor bottom electrode, a memory resistor material over the memory resistor bottom electrode, and a memory resistor top electrode over the memory resistor material. An MSM bottom electrode overlies the memory resistor top electrode, a semiconductor layer overlies the MSM bottom electrode, and an MSM top electrode overlies the semiconductor layer. The MSM bottom electrode can be a material such as Pt, Ir, Au, Ag, TiN, or Ti. The MSM top electrode can be a material such as Pt, Ir, Au, TiN, Ti, or Al. The semiconductor layer can be amorphous Si, ZnO2, or InO2.

Abstract: A method of forming a tungsten pattern includes forming a preliminary tungsten pattern on a substrate and partially removing a surface of the preliminary tungsten pattern using deionized water to form the tungsten pattern.

Abstract: A trench capacitor structure includes a semiconductor substrate comprising thereon a STI structure. A capacitor deep trench is etched into the semiconductor substrate. Collar oxide layer is disposed on inner surface of the capacitor deep trench. A first doped polysilicon layer is disposed on the collar oxide layer and on the exposed bottom of the capacitor deep trench. A capacitor dielectric layer is formed on the first doped polysilicon layer. A second doped polysilicon layer is formed on the capacitor dielectric layer. A deep ion well is formed in the semiconductor substrate, wherein the deep ion well is electrically connected with the first doped polysilicon layer through the bottom of the capacitor deep trench. A passing gate insulation (PGI) layer is formed on the second doped polysilicon layer and on the STI structure.

Abstract: The present invention relates to a bit line barrier metal layer for a semiconductor device and a process for preparing the same, the process comprising: forming bit line contact on an insulation layer vapor-deposited on an upper part of a substrate so as to expose an ion implantation region; vapor-depositing a first barrier metal layer of a Ti film on the entire upper surface thereof; and vapor-depositing, on the upper part of the Ti film, a second barrier metal layer of a ZrB2 film having different upper and lower Boron concentrations, by RPECVD controlling the presence/absence of H2 plasma, wherein the barrier metal layer includes the Ti film, lower ZrB2 film and upper a ZrB2 film sequentially stacked between tungsten bit lines and ion implantation region of a semiconductor substrate.

Abstract: Bit lines having first conductive patterns and bit line mask patterns are formed on a first insulating layer between capacitor contact regions of a substrate. An oxide second insulating layer is formed on the bit lines and contact patterns are formed to open storage node contact hole regions corresponding to portions of the second insulating layer. First spacers are formed on sidewalls of the etched portions. The second and first insulating layers are etched to form storage node contact holes exposing the capacitor contact regions. Simultaneously, second spacers of the second insulating layer are formed beneath the first spacers. A second conductive layer fills the storage node contact holes to form storage node contact pads. A loss of the bit line mask pattern decreases due to the reduced thickness of the bit line mask pattern and a bit line loading capacitance decreases due to the second spacers.

Abstract: A thin film array panel is provided, which includes: a gate line formed on a substrate; a first insulating layer formed on the gate line; a semiconductor layer formed on the gate insulating layer; a data line formed on the gate insulating layer and intersecting the gate line; a drain electrode formed at least on the semiconductor layer; a conductor arranged in parallel to the data line; a second insulating layer formed on the data line, the drain electrode, and the conductor and having a first contact hole exposing a portion of the drain electrode; and a pixel electrode formed on the second insulating layer, connected to the drain electrode through the first contact hole, fully covering the data line.