Abstract: Systems and methods associated with semiconductor articles are disclosed, including forming a first layer of material on a substrate, etching trenches within regions defining a passive element in the first layer, forming metal regions on sidewalls of the trenches, and forming a region of dielectric or polymer material over or in the substrate. Moreover, an exemplary method may also include forming areas of metal regions on the sidewalls of the trenches such that planar strip portions of the areas form electrically conductive regions of the passive element(s) that are aligned substantially perpendicularly with respect to a primary plane of the substrate. Other exemplary embodiments may comprise various articles or methods including capacitive and/or inductive aspects, Titanium- and/or Tantalum-based resistive aspects, products, products by processes, packages and composites consistent with one or more aspects of the innovations set forth herein.

Abstract: A power supply circuit includes first and second switching MOSFETS. A semiconductor device, including the second switching MOSFET, has a plurality of transistor cell regions disposed in a semiconductor substrate. A source electrode of the second MOSFET is disposed over a main surface of the semiconductor substrate and is in contact with a top surface of a source region in each of the plurality of transistor cell regions. A drain electrode of the second MOSFET is disposed over a back surface of the semiconductor substrate and is electrically connected to the semiconductor substrate. A Schottky cell region is disposed between the plurality of transistor cell regions in the semiconductor substrate. The source electrode is in contact with a part of the main surface of the semiconductor so as to form a Schottky junction in the Schottky cell region.

Abstract: A method for fabricating a semiconductor device, including forming a trench by etching a semiconductor substrate, forming a gate insulation layer over a surface of the trench, forming a gate conductive layer over the gate insulation layer, performing a first recess process by etching the gate conductive layer, forming a protection pattern over the gate insulation layer, and performing a second recess process by etching the gate conductive layer.

Abstract: Disclosed are a solar cell and a manufacturing method thereof. The solar cell in accordance with an embodiment of the present invention includes: a substrate having a plurality of holes formed on one surface thereof; a metal layer formed on an inner wall of the hole and on one surface of the substrate; a p-type semiconductor coated on the metal layer; an n-type semiconductor formed inside the hole and on one surface of the substrate; a transparent conductive oxide formed on the n-type semiconductor; and an electrode terminal formed on the p-type semiconductor and on the transparent conductive oxide.

Abstract: A method of manufacturing a semiconductor device having a charge control trench and an active control trench with a thick oxide bottom includes forming a drift region, a well region extending above the drift region, an active trench extending through the well region and into the drift region, a charge control trench extending deeper into the drift region than the active trench, an oxide film that fills the active trench, the charge control trench and covers a top surface of the substrate, an electrode in the active trench, and source regions. The method also includes etching the oxide film off the top surface of the substrate and inside the active trench to leave a substantially flat layer of thick oxide having a target thickness at the bottom of the active trench.

Abstract: Provided is a self aligned filed effect transistor structure. The self aligned field effect transistor structure includes: an active region on a substrate; a U-shaped gate insulation pattern on the active region; and a gate electrode self-aligned by the gate insulation pattern and disposed in an inner space of the gate insulation pattern.

Abstract: A method for forming a trench-gate FET includes the following steps. A plurality of trenches is formed extending into a semiconductor region. A gate dielectric is formed extending along opposing sidewalls of each trench and over mesa surfaces of the semiconductor region between adjacent trenches. A gate electrode is formed in each trench isolated from the semiconductor region by the gate dielectric. Well regions of a second conductivity type are formed in the semiconductor region. Source regions of the first conductivity type are formed in upper portions of the well regions. After forming the source regions, a salicide layer is formed over the gate electrode in each trench abutting portions of the gate dielectric. The gate dielectric prevents formation of the salicide layer over the mesa surfaces of the semiconductor region between adjacent trenches.

Abstract: A METAL-INSULATOR-METAL structured capacitor is formed with polysilicon instead of an oxide film as a sacrificial layer material that defines a storage electrode region. A MPS (Meta-stable Poly Silicon) process is performed to increase the surface area of the sacrificial layer that defines the storage electrode region and also increase the area of the storage electrode formed over sacrificial layer. This process results in increasing the capacity of the capacitor in a stable manner.

Abstract: A method for forming a shielded gate field effect transistor (FET) includes forming a plurality of trenches in a semiconductor region and forming a shield electrode in a bottom portion of each trench. The method also includes forming a dielectric layer comprising a first oxide layer and a nitride layer both laterally extending over the shield electrode. The method also includes forming a gate electrode over the dielectric layer.

Abstract: A method according to example embodiments includes forming isolation regions in a substrate, the isolation regions defining active regions. Desired regions of the active regions and the isolation regions are removed, thereby forming recess channel trenches to a desired depth. The recess channel trenches are fog to have a first region in contact with the active regions and a second region in contact with the isolation regions. A width of a bottom surface of the recess channel trenches is less than that of a top surface thereof. The active regions and the isolation regions are annealed to uplift the bottom surface of the recess channel trenches. An area of the bottom surface of the first region is increased. A depth of the bottom surface of the first region is reduced.

Abstract: The invention includes methods of forming recessed access devices. A substrate is provided to have recessed access device trenches therein. A pair of the recessed access device trenches are adjacent one another. Electrically conductive material is formed within the recessed access device trenches, and source/drain regions are formed proximate the electrically conductive material. The electrically conductive material and source/drain regions together are incorporated into a pair of adjacent recessed access devices. After the recessed access device trenches are formed within the substrate, an isolation region trench is formed between the adjacent recessed access devices and filled with electrically insulative material to form a trenched isolation region.

Abstract: A trench MOSFET structure having improved avalanche capability is disclosed, wherein the source region is formed by performing source Ion Implantation through contact open region of a contact interlayer, and further diffused to optimize a trade-off between Rds and the avalanche capability. Thus, only three masks are needed in fabrication process, which are trench mask, contact mask and metal mask. Furthermore, said source region has a doping concentration along channel region lower than along contact trench region, and source junction depth along channel region shallower than along contact trench, and source doping profile along surface of epitaxial layer has Guassian-distribution from trenched source-body contact to channel region.

Abstract: A method of forming a field effect transistor includes: forming a trench in a semiconductor region; forming a shield electrode in the trench; performing an angled sidewall implant of impurities of the first conductivity type to form a channel enhancement region adjacent the trench; forming a body region of a second conductivity type in the semiconductor region; and forming a source region of the first conductivity type in the body region, the source region and an interface between the body region and the semiconductor region defining a channel region therebetween, the channel region extending along the trench sidewall. The channel enhancement region partially extends into a lower portion of the channel region to thereby reduce a resistance of the channel region.

Abstract: According to some embodiments of the invention, transistors have channel regions between channel-portion holes. Methods of forming the same include at least two channel-portion holes disposed in a semiconductor substrate. Line patterns are formed in parallel to be spaced apart from each other on a main surface of the semiconductor substrate to fill the channel-portion holes. A channel region is disposed in the semiconductor substrate below the line patterns. At this time, the channel region is formed between the channel-portion holes and also covers lower portions of the channel-portion holes. Driving current capability and refresh characteristics of DRAMs utilizing the inventive transistors are improved.

Abstract: In a semiconductor memory device having a vertical channel transistor a body of which is connected to a substrate and a method of fabricating the same, the semiconductor memory device includes a semiconductor substrate including a plurality of pillars arranged spaced apart from one another, and each of the pillars includes a body portion and a pair of pillar portions extending from the body portion and spaced apart from each other. A gate electrode is formed to surround each of the pillar portions. A bitline is disposed on the body portion to penetrate a region between a pair of the pillar portions of each of the first pillars arranged to extend in a first direction. A wordline is disposed over the bitline, arranged to extend in a second direction intersecting the first direction, and configured to contact the side surface of the gate electrode. A first doped region is formed in the upper surface of each of the pillar portions of the pillar.

Abstract: Channels of two transistors are vertically formed on portions of two opposite side surfaces of one active region, and gate electrodes are vertically formed on a device isolation layer contacting the channels of the active region. A common bit line contact plug is formed in the central portions of the active region, two storage node contact plugs are formed on both sides of the bit line contact plug, and an insulating spacer is formed on a side surface of the bit line contact plug. A word line, a bit line, and a capacitor are sequentially stacked on the semiconductor substrate, like a conventional semiconductor memory device. Thus, effective space arrangement of a memory cell is possible such that a 4F2 structure is constituted, and a conventional line and contact forming process can be applied such that highly integrated semiconductor memory device is readily fabricated.

Abstract: A method of fabricating a semiconductor device comprises forming a hard mask on a substrate having a top substrate surface, forming a trench in the substrate, through the hard mask, depositing gate material in the trench, where the amount of gate material deposited in the trench extends beyond the top substrate surface, and removing the hard mask to leave a gate structure that extends substantially above the top substrate surface.

Abstract: A semiconductor device, including a MOSFET, has a plurality of transistor cell regions disposed in a semiconductor substrate. A source electrode of the MOSFET is disposed over a main surface of the semiconductor substrate and is in contact with a top surface of a source region in each of the plurality of transistor cell regions. A drain electrode of the MOSFET is a disposed over a back surface of the semiconductor substrate and is electrically connected to the semiconductor substrate. A Schottky cell region is disposed between the plurality of transistor cell regions in the semiconductor substrate. The source electrode is in contact with a part of the main surface of the semiconductor so as to form a Schottky junction in the Schottky cell region.

Abstract: A semiconductor device includes a substrate where an isolation region and a plurality of active regions are defined, an anti-interference layer formed over the substrate in the isolation region, and a gate line simultaneously crossing the active region and the anti-interference layer.

Abstract: In a replacement gate approach, a top area of a gate opening has a superior cross-sectional shape which is accomplished on the basis of a plasma assisted etch process or an ion sputter process. During the process, a sacrificial fill material protects sensitive materials, such as a high-k dielectric material and a corresponding cap material. Consequently, the subsequent deposition of a work function adjusting material layer may not result in a surface topography which may result in a non-reliable filling-in of the electrode metal. In some illustrative embodiments, the sacrificial fill material may also be used as a deposition mask for avoiding the deposition of the work function adjusting metal in certain gate openings in which a different type of work function adjusting species is required.

Abstract: A method for fabricating a semiconductor device includes the following steps. A device isolation layer with a trench type is etched in a predetermined portion of a substrate to define an active region. Predetermined portions where gate lines traverse in the device isolation layer are etched to a certain depth to form a plurality of first recesses. A pair of gate lines filling the first recesses and traversing over the active region is formed. Portions of the active region which storage nodes contact on one sides of the gate lines are etched to form a plurality of second recesses. An ion-implantation process is performed to form a plurality of first junction regions beneath the second recesses and to form a second junction region in a portion of the active region between the gate lines such that the second junction region contacts bit lines.

Abstract: The invention includes a semiconductor structure having a gateline lattice surrounding vertical source/drain regions. In some aspects, the source/drain regions can be provided in pairs, with one of the sourcedrain regions of each pair extending to a digit line and the other extending to a memory storage device, such as a capacitor. The source/drain regions extending to the digit line can have the same composition as the source/drain regions extending to the memory storage devices, or can have different compositions from the sourcedrain regions extending to the memory storage devices. The invention also includes methods of forming semiconductor structures. In exemplary methods, a lattice comprising a first material is provided to surround repeating regions of a second material. At least some of the first material is then replaced with a gateline structure, and at least some of the second material is replaced with vertical source/drain regions.

Abstract: A method for manufacturing a photodiode array includes providing a semiconductor substrate having first and second main surfaces opposite to each other. The semiconductor substrate has a first layer of a first conductivity proximate the first main surface and a second layer of a second conductivity proximate the second main surface. A via is formed in the substrate which extends to a first depth position relative to the first main surface. The via has a first aspect ratio. Generally simultaneously with forming the via, an isolation trench is formed in the substrate spaced apart from the via which extends to a second depth position relative to the first main surface. The isolation trench has a second aspect ratio different from the first aspect ratio.

Abstract: The invention includes methods of forming recessed access devices. A substrate is provided to have recessed access device trenches therein. A pair of the recessed access device trenches are adjacent one another. Electrically conductive material is formed within the recessed access device trenches, and source/drain regions are formed proximate the electrically conductive material. The electrically conductive material and source/drain regions together are incorporated into a pair of adjacent recessed access devices. After the recessed access device trenches are formed within the substrate, an isolation region trench is formed between the adjacent recessed access devices and filled with electrically insulative material to form a trenched isolation region.

Abstract: Known drawbacks associated with use of tungsten as a gate material in a semiconductor device are prevented. A gate oxide layer, a polysilicon layer, and a nitride layer are sequentially formed on a semiconductor substrate having a isolation layer for defining the active region. A groove is formed by etching the nitride layer. A metal nitride layer is formed to an U shape in the groove, and then a metal layer is formed to bury the groove. A hard mask layer is formed for defining a gate forming region on the nitride layer, the metal nitride layer, and the metal layer. A metal gate is formed by etching the nitride layer, the polysilicon layer, and the gate oxide layer using the hard mask layer as an etch barrier.

Abstract: A semiconductor device including a MOSFET has a plurality of transistor cell regions disposed on a semiconductor substrate and a Schottky cell region disposed between the plurality of transistor cell regions. Each transistor cell region has a plurality of first trenches disposed in a main surface of the semiconductor substrate, a well region between the plurality of first trenches, a first gate insulating film and a first gate electrode of the MOSFET in each first trench, and a source region of the MOSFET in each well region. The Schottky cell region has a plurality of second trenches disposed in the main surface of the semiconductor substrate, a second gate insulating film and a second gate electrode of the MOSFET in each second trench, gate lead-out wiring connected to each second gate electrode, and a plurality of guard ring regions enclosing the respective second trenches.

Abstract: The invention includes a method of forming a semiconductor construction. Dopant is implanted into the upper surface of a monocrystalline silicon substrate. The substrate is etched to form a plurality of trenches and cross-trenches which define a plurality of pillars. After the etching, dopant is implanted within the trenches to form a source/drain region that extends less than an entirety of the trench width. The invention includes a semiconductor construction having a bit line disposed within a semiconductor substrate below a first elevation. A wordline extends elevationally upward from the first elevation and substantially orthogonal relative to the bit line. A vertical transistor structure is associated with the wordline. The transistor structure has a channel region laterally surrounded by a gate layer and is horizontally offset relative to the bit line.

Abstract: A trench MOSFET structure having improved avalanche capability is disclosed, wherein the source region is formed by performing source Ion Implantation through contact open region of a thick contact interlayer, and further diffused to optimize a trade-off between Rds and the avalanche capability. Thus, only three masks are needed in fabrication process, which are trench mask, contact mask and metal mask. Furthermore, said source region has a doping concentration along channel region lower than along contact trench region, and source junction depth along channel region shallower than along contact trench, and source doping profile along surface of epitaxial layer has Gaussian-distribution from trenched source-body contact to channel region.

Abstract: A recessed dielectric antifuse device includes a substrate and laterally spaced source and drain regions formed in the substrate. A recess is formed between the source and drain regions. A gate and gate oxide are formed in the recess and lightly doped source and drain extension regions contiguous with the laterally spaced source and drain regions are optionally formed adjacent the recess. Programming of the recessed dielectric antifuse is performed by application of power to the gate and at least one of the source region and the drain region to breakdown the dielectric, which minimizes resistance between the gate and the channel.

Abstract: Example embodiments relate to a non-volatile semiconductor memory device and a method of manufacturing the same. A semiconductor device includes an isolation layer protruding from a substrate, a spacer, a tunnel insulation layer, a floating gate, a dielectric layer pattern and a control gate. The spacer may be formed on a sidewall of a protruding portion of the isolation layer. The tunnel insulation layer may be formed on the substrate between adjacent isolation layers. The floating gate may be formed on the tunnel insulation layer. The floating gate contacts the spacer and has a width that gradually increases from a lower portion toward an upper portion. The dielectric layer pattern and the control gate may be sequentially formed on the floating gate.

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: According to some embodiments of the invention, a method of forming a transistor includes forming a device isolation layer in a semiconductor substrate. The device isolation layer is formed to define at least one active region. A channel region is formed in a predetermined portion of the active region of the semiconductor substrate. Two channel portion holes are formed to extend downward from a main surface of the semiconductor substrate to be in contact with the channel region. Gate patterns fill the channel portion holes and cross the active region. The resulting transistor is capable of ensuring a constant threshold voltage without being affected by an alignment state of the channel portion hole and the gate pattern.

Abstract: A semiconductor device includes an active region including a surface region and a first recess formed below the surface region, the active region extending along a first direction; a device isolation structure provided on an edge of the active region; a gate line traversing over the surface region of the active region along a second direction orthogonal to the first direction; a second recess formed in the device isolation structure to receive a given portion of the gate line into the second recess; a first junction region formed in the active region beneath the first recess and on a first side of the gate line; and a second junction region formed on a second side of the gate line and above the first junction region, wherein the first and second junction regions define a vertical-type channel that extends along lateral and vertical directions.

Abstract: Methods of forming pad structures are provided in which a first contact region and second contact regions are formed in an active region of a substrate. An insulating interlayer is formed on the substrate. The insulating interlayer has a first opening that exposes the first contact region and the second contact regions. First conductive pads are formed in the first opening. Each first conductive pad is in electrical contact with a respective one of the second contact regions. Spacers are formed, where each spacer is on a sidewall of a respective one of the first conductive pads. Finally, a second conductive pad is formed between the first conductive pads and in electrical contact with the first contact region to complete the pad structure.

Abstract: An embodiment of the invention provides a method for forming a semiconductor device comprising providing a substrate with a pad layer formed thereon. The pad layer and the substrate are patterned to form a plurality of trenches. A trench top insulating layer is formed in each trench. Wherein the trench top insulating layer protrudes from the substrate and has an extension portion extending to the pad layer. The pad layer and the substrate are etched by using the trench top insulating layers and the extension portions as a mask to form a recess in the substrate. And a recess gate is formed in the recess.

Abstract: Gate trenches 108 are formed in a memory cell region M using a silicon nitride film 103 as a mask in a state in which the semiconductor substrate 100 in a P-type peripheral circuit region P and an N-type peripheral circuit region N is covered by a gate insulating film 101s, a protective film 102, and the silicon nitride film 103. A gate insulating film 109 is then formed on the inner walls of the gate trenches 108, and a silicon film 110 that includes an N-type impurity is embedded in the gate trenches 108. The silicon nitride film 103 is then removed, and a non-doped silicon film is formed on the entire surface, after which a P-type impurity is introduced into the non-doped silicon film on region P, and an N-type impurity is introduced into the non-doped silicon film on regions M and N.

Abstract: A flash memory and a flash memory fabrication method for increasing the coupling ratio by HSG including forming a STI region on a silicon substrate to define an active region, forming a tunneling oxide layer on the active region, and depositing an amorphous silicon layer on the silicon substrate. The method also includes patterning the amorphous silicon layer along a bit line direction, forming an embossed silicon layer including HSGs on the patterned amorphous silicon layer, and sequentially depositing an ONO layer and a polysilicon layer for a control gate on the resulting structure. The method further includes forming a photoresist pattern on the polysilicon layer, and forming a control gate by etching the polysilicon layer using the photoresist pattern as a mask, and simultaneously forming a floating gate along the bit line.

Abstract: A method of forming a power device includes providing a substrate, a semiconductor layer having at least a trench and being disposed on the substrate, a gate insulating layer covering the semiconductor layer, and a conductive material disposed in the trench, performing an ion implantation process to from a body layer, performing a tilted ion implantation process to from a heavy doped region, forming a first dielectric layer overall, performing a chemical mechanical polishing process until the body layer disposed under the heavy doped region is exposed to form source regions on the opposite sides of the trench, and forming a source trace directly covering the source regions disposed on the opposite sides of the trench.

Abstract: A semiconductor device includes a semiconductor substrate provided with an active region including a gate forming area, a source forming area and a drain forming area. A recess is formed in the gate forming area. A gate is formed over the gate forming area that is formed with the recess and includes an insulation layer formed at an upper end portion of a side wall of the recess that is in contact with the source forming area. A source area and a drain area are formed in the active region on opposite sides of the gate.

Abstract: A method forming a semiconductor device includes forming a domed gate oxide film to relieve stress resulting from a thermal expansion rate difference of an oxide film and silicon film during a subsequent thermal process and preventing leakage current between source/drain regions through thickness regulation of the gate oxide film to improve refresh characteristics.

Abstract: Semiconductor devices including an isolation layer on a semiconductor substrate are provided. The isolation layer defines an active region of the semiconductor substrate. The device further includes an upper gate electrode crossing over the active region and extending to the isolation layer and lower active gate electrode. The lower active gate electrode includes a first active gate electrode extending from the upper gate electrode to the active region and a second active gate electrode below the first active gate electrode and having a greater width than a width of the first active gate electrode. The device further includes a lower field gate electrode that extends from the upper gate electrode to the isolation layer and has a bottom surface that is at a lower level than a bottom surface of the active gate electrode such that the sidewalls of the active region are covered below the lower active gate electrode. Related methods of fabricating semiconductor devices are also provided herein.

Abstract: Known drawbacks associated with use of tungsten as a gate material in a semiconductor device are prevented. A gate oxide layer, a polysilicon layer, and a nitride layer are sequentially formed on a semiconductor substrate having a isolation layer for defining the active region. A recess is defined by etching the nitride layer. A metal nitride layer is formed in the recess in an U shape, and then a metal layer is formed to bury the recess. A hard mask layer is formed for defining a gate forming region on the nitride layer, the metal nitride layer, and the metal layer. A metal gate is formed by etching the nitride layer, the polysilicon layer, and the gate oxide layer using the hard mask layer as an etch barrier.

Abstract: Semiconductor memory devices having recessed access devices are disclosed. In some embodiments, a method of forming the recessed access device includes forming a device recess in a substrate material that extends to a first depth in the substrate that includes a gate oxide layer in the recess. The device recess may be extended to a second depth that is greater that the first depth to form an extended portion of the device recess. A field oxide layer may be provided within an interior of the device recess that extends inwardly into the interior of the device recess and into the substrate. Active regions may be formed in the substrate that abut the field oxide layer, and a gate material may be deposited into the device recess.

Abstract: A method for forming an alignment mark comprises forming an etch stop film and an interlayer insulating film over a semiconductor substrate including a cell region and a scribe region, etching a predetermined region of the interlayer insulating film and the etch stop film to form a storage node region in the cell region and an alignment mark region in the scribe region, forming a layer for storage node over an entire surface of the resultant including the storage node region in the cell region and the alignment mark region in the scribe region, etching the layer for storage node until the interlayer insulting film is exposed, and removing the interlayer insulating film to form a capacitor in the cell region and an alignment mark in the scribe region.

Abstract: A fabrication method of a trenched power MOSFET with low gate impedance is provided. The fabrication method comprising the steps of: forming a plurality of trenches in an epitaxial layer; forming a gate oxide layer on the epitaxial layer; forming a plurality of polysilicon gates in the trenches; implanting dopants with a first conductivity type into the epitaxial layer; driving-in the dopants in an oxygen-free environment to form a body; implanting dopants with a second conductivity type into the body; driving-in the dopants with the second conductivity type in an oxygen-free environment to form a plurality of source regions; forming self alignment silicide on the polysilicon gates by using the gate oxide layer as a mask; depositing a dielectric layer on the epitaxial layer and forming a window therein exposing the source regions; and forming a heavily doped region of the first conductivity type in the body beneath the window.

Abstract: Systems and methods associated with semiconductor articles are disclosed, including forming a first layer of material on a substrate, etching trenches within regions defining a passive element in the first layer, forming metal regions on sidewalls of the trenches, and forming a region of dielectric or polymer material over or in the substrate. Moreover, an exemplary method may also include forming areas of metal regions on the sidewalls of the trenches such that planar strip portions of the areas form electrically conductive regions of the passive element(s) that are aligned substantially perpendicularly with respect to a primary plane of the substrate. Other exemplary embodiments may comprise various articles or methods including capacitive and/or inductive aspects, Titanium- and/or Tantalum-based resistive aspects, products, products by processes, packages and composites consistent with one or more aspects of the innovations set forth herein.

Abstract: A method for forming a memory device with a recessed gate is disclosed. A substrate with a pad layer thereon is provided. The pad layer and the substrate are patterned to form at least two trenches. A deep trench capacitor is formed in each trench. A protrusion is formed on each deep trench capacitor, wherein a top surface level of each protrusion is higher than that of the pad layer. Spacers are formed on sidewalls of the protrusions, and the pad layer and the substrate are etched using the spacers and the protrusions as a mask to form a recess. A recessed gate is formed in the recess.

Abstract: A vertical transistor forming method includes forming a first pillar above a first source/drain and between second and third pillars, providing a first recess between the first and second pillars and a wider second recess between the first and third pillars, forming a gate insulator over the first pillar, forming a front gate and back gate over opposing sidewalls of the first pillar by depositing a gate conductor material within the first and second recesses and etching the gate conductor material to substantially fill the first recess, forming the back gate, and only partially fill the second recess, forming the front gate, forming a second source/drain elevationally above the first source/drain, and providing a transistor channel in the first pillar. The channel is operationally associated with the first and second sources/drains and with the front and back gates to form a vertical transistor configured to exhibit a floating body effect.

Abstract: The invention includes a method in which a semiconductor substrate is provided to have a memory array region, and a peripheral region outward of the memory array region. Paired transistors are formed within the memory array region, with such paired transistors sharing a source/drain region corresponding to a bitline contact location, and having other source/drain regions corresponding to capacitor contact locations. A peripheral transistor gate is formed over the peripheral region. Electrically insulative material is formed over the peripheral transistor gate, and also over the bitline contact location. The insulative material is patterned to form sidewall spacers along sidewalls of the peripheral transistor gate, and to form a protective block over the bitline contact location. Subsequently, capacitors are formed which extend over the protective block, and which electrically connect with the capacitor contact locations. The invention also includes semiconductor constructions.

Abstract: A method for manufacturing a photodiode array includes providing a semiconductor substrate having first and second main surfaces opposite to each other. The semiconductor substrate has a first layer of a first conductivity proximate the first main surface and a second layer of a second conductivity proximate the second main surface. A via is formed in the substrate which extends to a first depth position relative to the first main surface. The via has a first aspect ratio. Generally simultaneously with forming the via, an isolation trench is formed in the substrate spaced apart from the via which extends to a second depth position relative to the first main surface. The isolation trench has a second aspect ratio different from the first aspect ratio.