Abstract: A stack pad layers including a first pad oxide layer, a pad nitride layer, and a second pad oxide layer are formed on a semiconductor-on-insulator (SOI) substrate. A deep trench extending below a top surface or a bottom surface of a buried insulator layer of the SOI substrate and enclosing at least one top semiconductor region is formed by lithographic methods and etching. A stress-generating insulator material is deposited in the deep trench and recessed below a top surface of the SOI substrate to form a stress-generating buried insulator plug in the deep trench. A silicon oxide material is deposited in the deep trench, planarized, and recessed. The stack of pad layer is removed to expose substantially coplanar top surfaces of the top semiconductor layer and of silicon oxide plugs. The stress-generating buried insulator plug encloses, and generates a stress to, the at least one top semiconductor region.

Abstract: Properties of a hard mask liner are used against the diffusion of a removal agent to prevent air cavity formation in specific areas of an interconnect stack. According to one embodiment, there is provided a method in which there is defined a portion on a surface of an IC interconnect stack as being specific to air cavity introduction, with the defined portion being smaller than the surface of the substrate. At least one metal track is produced within the interconnect stack, and there is deposited at least one interconnect layer having a sacrificial material and a permeable material within the interconnect stack. There is defined at least one trench area surrounding the defined portion and forming at least one trench, and a hard mask layer is deposited to coat the trench. At least one air cavity is formed below the defined portion of the surface by using a removal agent for removing the sacrificial material to which the permanent material is resistant.

Abstract: A method for producing an electrode in a semiconductor layer includes providing a substrate with a first surface and a second surface, forming a first trench having sidewalls and extending into the substrate from the first surface and forming a plug in the first trench. The method further includes reducing a thickness of the semiconductor substrate by removing semiconductor material beginning at the first surface so as to at least partially uncover sidewalls of the plug and forming a semiconductor layer on the semiconductor substrate, the semiconductor layer at least partially covering the uncovered sidewalls of the plug, and having an upper surface.

Abstract: A semiconductor device according to one embodiment includes: an n-type transistor comprising a first gate electrode formed on a semiconductor substrate via a first gate insulating film, a first channel region formed in the semiconductor substrate under the first gate insulating film, and first source/drain regions formed in the semiconductor substrate on both sides of the first channel region, the first gate electrode comprising a first metal layer and a first conductive layer thereon; and a p-type transistor comprising a second gate electrode formed on the semiconductor substrate via a second gate insulating film, a second channel region formed in the semiconductor substrate under the second gate insulating film, and second source/drain regions formed in the semiconductor substrate on both sides of the second channel region, the second gate electrode comprising a second metal layer and a second conductive layer thereon, the second metal layer being thicker than the first metal layer and having the same const

Abstract: Provided is a LOCOS offset MOS field-effect transistor in which a first lightly-doped N-type drain offset region with a LOCOS oxide film and a second lightly-doped N-type drain offset region without a LOCOS oxide film are formed in a drain-side offset region, and both the regions are covered with a gate electrode. Provision of the first lightly-doped N-type drain offset region mitigates an electric field applied to the first lightly-doped N-type drain offset region to increase a breakdown voltage. Provision of the second lightly-doped N-type drain offset region increases carriers within the second lightly-doped N-type drain offset region to obtain a high current drivability.

Abstract: Embodiments relate to a semiconductor device and a method of manufacturing a semiconductor. In embodiments, the method may include a first exposure step of performing an exposure process for forming a first photoresist on a semiconductor substrate at one side of the outside of a trench pattern which will be formed, a first etching step of performing a predetermined dry etching method with respect to the first photoresist, a second exposure step of performing an exposure process for forming a second photoresist at the other side of the outside of the trench pattern, which is a side opposite to the first photoresist, and a second etching step of performing the predetermined dry etching method with respect to the second photoresist.

Abstract: Winged via structures to increase overlay margin are generally described. In one example, a method comprises depositing a sacrificial layer to an interlayer dielectric, the interlayer dielectric being coupled with a semiconductor substrate, forming at least one trench structure in the sacrificial layer wherein the trench structure comprises a first direction along a length of the trench structure and a second direction along a width of the trench structure wherein the second direction is substantially perpendicular to the first direction, depositing a light sensitive material to the trench structure and the sacrificial layer, and patterning at least one winged via structure in the light sensitive material to overlay the trench structure wherein the winged via structure extends in the second direction beyond the width of the trench structure onto the sacrificial layer.

Abstract: In the present invention, there is provided a semiconductor device including: element isolation regions formed in a state of being buried in a semiconductor substrate such that an element formation region of the semiconductor substrate is interposed between the element isolation regions; a gate electrode formed on the element formation region with an gate insulating film interposed between the gate electrode and the element formation region, the gate electrode being formed so as to cross the element formation region; and source-drain regions formed in the element formation region on both sides of the gate electrode, wherein a channel region made of the element formation region under the gate electrode is formed so as to project from the element isolation regions, and the source-drain regions are formed to a position deeper than surfaces of the element isolation regions.

Abstract: An embodiment of a memory device has a plurality of conductive plugs formed on a semiconductor substrate and a pair of successively adjacent first and second bit lines overlying and in contact with each of the conductive plugs.

Abstract: A semiconductor device having a buried gate that can realize a reduction in gate-induced drain leakage is presented. The semiconductor device includes a semiconductor substrate, a buried gate, and a barrier layer. The semiconductor substrate has a groove. The buried gate is formed in a lower portion of the groove and has a lower portion wider than an upper portion. The barrier layer is formed on sidewalls of the upper portion of the buried gate.

Abstract: Electronic apparatus and methods of forming the electronic apparatus include a hafnium lanthanide oxynitride film on a substrate for use in a variety of electronic systems. The hafnium lanthanide oxynitride film may be structured as one or more monolayers. Metal electrodes may be disposed on a dielectric containing a hafnium lanthanide oxynitride film.

Abstract: A semiconductor device has first wiring layers 30 and a plurality of dummy wiring layers 32 that are provided on the same level as the first wiring layers 30. The semiconductor device defines a row direction, and first virtual linear lines L1 extending in a direction traversing the row direction. The row direction and the first virtual linear lines L1 define an angle of 2-40 degrees, and the dummy wiring layers 32 are disposed in a manner to be located on the first virtual linear lines L1. The semiconductor device also defines a column direction perpendicular to the row direction, and second virtual linear lines L2 extending in a direction traversing the column direction. The column direction and the second virtual linear lines L2 define an angle of 2-40 degrees, and the dummy wiring layers 32 are disposed in a manner to be located on the second virtual linear lines L2.

Abstract: A semiconductor device includes a gate electrode having ends that overlap isolation regions, wherein the gate electrode is located over an active region located within a semiconductor substrate. A gate oxide is located between the gate electrode and the active regions, and source/drains are located adjacent the gate electrode and within the active region. An etch stop layer is located over the gate electrode and the gate electrode has at least one electrical contact that extends through the etch stop layer and contacts a portion of the gate electrode that in one embodiment overlies the active region, and in another embodiment is less than one alignment tolerance from the active region.

Abstract: An embodiment of a memory device has a plurality of conductive plugs formed on a semiconductor substrate and a pair of successively adjacent first and second bit lines overlying and in contact with each of the conductive plugs.

Abstract: Disclosed is a transistor that incorporates epitaxially deposited source/drain semiconductor films and a method for forming the transistor. A crystallographic etch is used to form recesses between a channel region and trench isolation regions in a silicon substrate. Each recess has a first side, having a first profile, adjacent to the channel region and a second side, having a second profile, adjacent to a trench isolation region. The crystallographic etch ensures that the second profile is angled so that all of the exposed recess surfaces comprise silicon. Thus, the recesses can be filled by epitaxial deposition without divot formation. Additional process steps can be used to ensure that the first side of the recess is formed with a different profile that enhances the desired stress in the channel region.

Abstract: A multilayer embedded stressor having a graded dopant profile for use in a semiconductor structure for inducing strain on a device channel region is provided. The inventive multilayer stressor is formed within areas of a semiconductor structure in which source/drain regions are typically located. The inventive multilayer stressor includes a first conformal epi semiconductor layer that is undoped or lightly doped and a second epi semiconductor layer that is highly dopant relative to the first epi semiconductor layer. The first and second epi semiconductor layers each have the same lattice constant, which is different from that of the substrate they are embedded in. The structure including the inventive multilayer embedded stressor achieves a good balance between stress proximity and short channel effects, and even eliminates or substantially reduces any possible defects that are typically generated during formation of the deep source/drain regions.

Abstract: A transistor device employed in a support circuit of a DRAM includes a semiconductor substrate having thereon a gate trench, a recessed gate embedded in the gate trench, a source doping region disposed at one side of the recessed gate, a drain doping region disposed at the other side of the recessed gate, and a gate dielectric layer between the recessed gate and the semiconductor substrate. The gate dielectric layer has at least two thicknesses that render the high-voltage transistor device asymmetric. The thicker gate dielectric layer is between the recessed gate and the drain doping region, while the thinner gate dielectric layer is between the recessed gate and the source doping region.

Abstract: In device isolation trenches, a first device-isolation insulator film is formed to have recesses thereon and a second device-isolation insulator film is formed in the recesses. The uppermost portions at both ends of the first device-isolation insulator film are located higher than the uppermost portions at both ends of the second device-isolation insulator film.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those structures may comprise a transistor comprising a metal gate disposed on a gate dielectric that is disposed on a substrate, and a source/drain region disposed adjacent a channel region of the transistor. The source/drain region comprises a source/drain extension comprising a vertex point, wherein a top surface of the channel region is substantially planar with the vertex point.

Abstract: A semiconductor memory device and a method for manufacturing the same are disclosed, which reduce parasitic capacitance generated between a storage node contact and a bit line of a high-integration semiconductor device. A method for manufacturing a semiconductor memory device includes forming a buried word line in an active region of a cell region, forming an insulation layer in the cell region and a lower electrode layer of a gate in a peripheral region so that a height of the insulation layer is substantially equal to that of the lower electrode layer, and providing a first conductive layer over the cell region and the peripheral region to form a bit line layer and an upper electrode layer.

Abstract: Various systems and methods related to semiconductor devices having a plurality of layers and having a first conductive trace on a first layer electrically connected to a second conductive trace on a second layer and electrically isolated from a third electrical trace on the second layer are provided. A semiconductor structure can include first, second and third layers. The first conducting layer may be etched to form a first trench for the first conductive trace. A layer of material on the second layer in the first trench can define a patch area, wherein the patch area is disposed in a location where the first trench crosses over the third electrical trace. A second trench may be etched in an area defined by the first trench and the patch area to remove material in the second layer exposed by the first trench, leaving material of the layer under the patch area.

Abstract: In a MIS-type semiconductor device having a trench gate structure, a withstand voltage is ensured without changing the thickness of a drift layer and on-resistance can be reduced without applying a high gate drive voltage. The lower half of a trench extending through a p-base region into an n-drift region is filled with a high-permittivity dielectric having a relative permittivity that is higher than that of a silicon oxide film, preferably a silicon nitride film, and an insulated gate structure including a gate insulator and a gate electrode is fabricated on the high-permittivity dielectric. The depth d2 of the deepest portion of the high-permittivity dielectric is designed to be deeper than the depth d1 of a depletion layer in the semiconductor region away from the high-permittivity dielectric.

Abstract: A method for fabricating a recess gate in a semiconductor device includes etching a silicon substrate to form a trench that defines an active region, forming a device isolation layer that gap-fills the trench, forming a hard mask layer over the silicon substrate, the hard mask layer comprising a stack of an oxide layer and an amorphous carbon layer, wherein the hard mask layer exposes a channel target region of the active region, and forming a recess region with a dual profile by first etching and second etching the channel target region using the hard mask layer as an etch barrier, wherein the second etching is performed after removing the amorphous carbon layer.

Abstract: A semiconductor device having a recessed active edge is provided. The semiconductor devices include an isolation layer disposed in a substrate to define an active region. A gate electrode is disposed to cross over the active region. A source region and a drain region are disposed in the active region on both sides of the gate electrode. A recessed region is disposed under the gate electrode and on an edge of the active region adjacent to the isolation layer. A bottom of the recessed region may be sloped down toward the isolation layer. The gate electrode may further extend into and fill the recessed region. That is, a gate extension may be disposed in the recessed region. A method of fabricating the semiconductor device is also provided.

Abstract: Disclosed is a method of fabricating a semiconductor device. The method can include forming a gate material layer on an inner surface of a trench which extends into a part of a semiconductor substrate by passing through an insulating layer formed on the semiconductor substrate, etching the gate material layer to an initial height in the trench above a top surface of the semiconductor substrate, etching the insulating layer such that the thickness of the insulating layer is reduced, forming a gate electrode in the trench by secondarily etching the etched gate material layer, and removing the insulating layer having the reduced thickness.

Abstract: An integrated circuit is disclosed that includes a first layer made of active semiconductor material and extending along a first side of a buried layer, and trench structures, which cut through the layer made of active semiconductor material and have dielectric wall regions, whereby the dielectric wall regions isolate electrically subregions of the layer, made of active semiconductor material in the lateral direction, and whereby the trench structures, furthermore, have first inner regions, which are filled with electrically conductive material and contact the buried layer in an electrically conductive manner. The integrated circuit is notable in that the first wall regions of the trench structures completely cut through the buried layer and the second wall regions of the trench structures extend into the buried layer, without cutting it completely. Furthermore, a method for manufacturing such an integrated circuit is disclosed.

Abstract: The present invention discloses semiconductor devices that can be manufactured utilizing standard process of manufacturing and that can hold information. In accordance with a presently preferred embodiment of the present invention, one or more semiconductor devices can be formed in a well on a substrate where isolation trenches surround one or more devices to create storage regions (floating wells) that is capable of holding a charge. Depending on the charge in the storage region (floating well), it can represent information. The semiconductor devices of the present invention can be manufactured using the standard process of manufacturing (bulk cmos processing).

Abstract: Devices, such as transistors, having vertical junction edges. More specifically, shallow trenches are formed in a substrate and filled with an isolation oxide. Cavities are formed in the isolation oxide and filled with a conductive material, such a doped polysilicon. Doped regions may be formed in the substrate directly adjacent the conductive material to form vertical junctions between the polysilicon and the exposed substrate at the trench sidewalls.

Abstract: Edges of source and drain regions along the direction of a channel of a field effect transistor are formed within an active area offset from the boundary between the active area and a shallow trench isolation structure. Such a structure may be manufactured by forming a gate electrode structure that overlies the boundary so that edges of the source and drain regions are self aligned to the edges of the gate electrode structure on the active area side of the boundary. Unnecessary portions of the gate electrode that does not overlie the source and drain regions may be removed to reduce parasitic capacitance. Shallow trench isolation edge current is eliminated since the semiconductor regions in the current path of the field effect transistor are offset from the boundary between the active area and the shallow trench isolation structure.

Abstract: The semiconductor device includes an active region, a recess channel region, a storage node junction region, a gate insulating film, and a gate electrode. The active region is defined by a device isolation structure formed in a semiconductor substrate, wherein a lower part of sidewalls of the active region is recessed. The recess channel is formed in the semiconductor substrate under the active region, wherein the recess channel has a vertical channel region and a horizontal channel region. The storage node junction region is formed over the device isolation structure and the semiconductor substrate. The gate insulating film is formed over the active region including the recess channel region. The gate electrode is formed over the gate insulating film to fill up the recess channel region.

Abstract: On a semiconductor substrate, a well is formed. In the well, one MOS transistor including a gate electrode, a source region, a source field limiting layer and a source/drain region, and another MOS transistor including a gate electrode, a drain electrode, a drain field limiting layer and a source/drain region are formed. The one and another MOS transistors are connected in series through the source/drain region common to the two transistors. Accordingly, a semiconductor device can be provided in which increase in pattern layout area is suppressed when elements including a high-breakdown voltage MOS transistor are to be connected in series.

Abstract: There is a method of manufacturing a semiconductor device with a semiconductor body comprising a semiconductor substrate and a semiconductor region which are separated from each other with an electrically insulating layer which includes a first and a second sub-layer which, viewed in projection, are adjacent to one another, wherein the first sub-layer has a smaller thickness than the second sub-layer, and wherein, in a first sub-region of the semiconductor region lying above the first sub-layer, at least one digital semiconductor element is formed and, in a second sub-region of the semiconductor region lying above the second sub-layer, at least one analog semiconductor element is formed. According to an example embodiment, the second sub-layer is formed in that the lower border thereof is recessed in the semiconductor body in relation to the lower border of the first sub-layer Fully depleted SOI devices are thus formed.

Abstract: The invention includes semiconductor constructions having trenched isolation regions. The trenches of the trenched isolation regions can include narrow bottom portions and upper wide portions over the bottom portions. Electrically insulative material can fill the upper wide portions while leaving voids within the narrow bottom portions. The trenched isolation regions can be incorporated into a memory array, and/or can be incorporated into an electronic system. The invention also includes methods of forming semiconductor constructions.

Abstract: A storage apparatus 10 is disclosed, that comprises a wiring substrate 11 having a first surface and a second surface, a flat type external connection terminal 12a disposed on the first surface of the wiring substrate 11, a semiconductor device 14 disposed on the second surface of the wiring substrate 11 and having a connection terminal 14a connected to the flat type external connection terminal 12a, a molding resin 15 for coating the semiconductor device 14 on the second surface of the wiring substrate 11, a card type supporting frame 10a having a concave portion or a hole portion fitting the wiring substrate 11, the semiconductor device 14, and the molding resin 15 in such a manner that the flat type external connection terminal 12a is exposed to the first surface of the wiring substrate 11, and adhesive resin a adhering integrally the flat type external connection terminal 12a, the wiring substrate 11, the semiconductor device 14, the molding resin 15, and the card type supporting frame 10a.

Abstract: A method of forming an isolation layer of a semiconductor device includes forming first trenches in an isolation region of a semiconductor substrate. A spacer is formed on sidewalls of each of the first trenches. Second trenches are formed in the isolation region below the corresponding first trenches. Each second trench is narrower and deeper than the corresponding first trench. A first oxide layer is formed on sidewalls and a bottom surface of each of the second trenches. The first trench is filled with an insulating layer.

Abstract: In device isolation trenches, a first device-isolation insulator film is formed to have recesses thereon and a second device-isolation insulator film is formed in the recesses. The uppermost portions at both ends of the first device-isolation insulator film are located higher than the uppermost portions at both ends of the second device-isolation insulator film.

Abstract: Embodiments relate to a semiconductor device. In embodiments, a semiconductor device may include a semiconductor substrate having isolation layers and a well region, a gate electrode formed within a trench having a predetermined depth in the well region, source/drain regions formed at both sides of the trench, respectively, an interlayer dielectric layer formed on the semiconductor substrate to have predetermined contact holes, and metal interconnections formed within the contact holes, respectively.

Abstract: A structure and method of fabricating a dual damascene interconnect structure, the structure including a dual damascene wire in a dielectric layer, the dual damascene wires extending a distance into the dielectric layer less than the thickness of the dielectric layer and dual damascene via bars integral with and extending from bottom surfaces of the dual damascene wires to a bottom surface of the dielectric layer.

Abstract: A semiconductor device includes a gate insulation film provided on a semiconductor substrate, a gate electrode provided on the gate insulation film, a pair of first diffusion layers, a pair of second diffusion layers which are provided in the semiconductor substrate in such a manner that the gate electrode is interposed between the second diffusion layers, the second diffusion layers have a lower impurity concentration than the first diffusion layers, contact wiring lines provided on the first diffusion layers, respectively, and a first insulation layer which is an insulation layer formed in at least one of the second diffusion layers between the gate electrode and the contact wiring lines, the first insulation layer having a greater depth in the semiconductor substrate than the first diffusion layer and a less depth than the second diffusion layer.

Abstract: Embodiments relate to a high voltage semiconductor device. The device includes a substrate having impurities of a first conductivity and having a first surface and a second surface, a gate electrode over the first surface, an LDD region having low concentration impurities of a second conductivity doped in the substrate at a first side of the gate electrode, a drain region having high concentration impurities of the second conductivity doped in the LDD region, a source region having high concentration impurities of the second conductivity doped in the substrate at a second side of the gate electrode, and spacers formed at sidewalls of the gate electrode. The first surface is higher than the second surface, and the source and LDD regions are at least partially formed in a region at the second surface. A bottom side of one of the spacers directly contacts the LLD region.

Abstract: An isolation structure of a semiconductor device is formed by forming a hard mask layer on a semiconductor substrate having active and field regions to expose the field region. A trench is defined by etching the exposed field region of the semiconductor substrate using the hard mask as an etch mask. An SOG layer is formed in the trench partially filling the trench. An amorphous aluminum oxide layer is formed on the resultant substrate including the SOG layer. An HDP layer is formed on the amorphous aluminum oxide layer to completely fill the trench. The HDP layer and the amorphous aluminum oxide layer are subjected to CMP to expose the hard mask. The hard mask and portions of the amorphous aluminum oxide layer that are formed on the HDP layer are removed. The amorphous aluminum oxide layer is crystallized.

Abstract: A storage apparatus 10 is disclosed, that comprises a wiring substrate 11 having a first surface and a second surface, a flat type external connection terminal 12a disposed on the first surface of the wiring substrate 11, a semiconductor device 14 disposed on the second surface of the wiring substrate 11 and having a connection terminal 14a connected to the flat type external connection terminal 12a, a molding resin 15 for coating the semiconductor device 14 on the second surface of the wiring substrate 11, a card type supporting frame 10a having a concave portion or a hole portion fitting the wiring substrate 11, the semiconductor device 14, and the molding resin 15 in such a manner that the flat type external connection terminal 12a is exposed to the first surface of the wiring substrate 11, and adhesive resin a adhering integrally the flat type external connection terminal 12a, the wiring substrate 11, the semiconductor device 14, the molding resin 15, and the card type supporting frame 10a.

Abstract: A metal oxide semiconductor (MOS) includes an isolation layer disposed in a semiconductor substrate to define an active region. A source region and a drain region are disposed on both sides of the active region such that a first direction is defined from the source region to the drain region. A channel recess is disposed in the active region between the source and drain regions. The channel recess has a convex surface when viewed from a cross-sectional view taken along a second direction orthogonal to the first direction. A gate electrode fills the channel recess and crosses the active region in the second direction. A gate insulating layer is interposed between the gate electrode and the active region.

Abstract: Provided are a field effect transistor, a method of manufacturing the same, and an electronic device including the field effect transistor. The field effect transistor may have a structure in which a double gate field effect transistor and a recess channel array transistor are formed in a single transistor in order to improve a short channel effect which occurs as field effect transistors become more highly integrated, a method of manufacturing the same, and an electronic device including the field effect transistor. The field effect transistor can exhibit stable device characteristics even when more highly integrated in such a manner that both the length and width of a channel increase and particularly the channel can be significantly long, and can be manufactured simply.

Abstract: A semiconductor device includes a device isolation structure formed on a semiconductor substrate to define an active region. A first Si-based epitaxial pattern is formed over the active region corresponding to a bit line contact region and a portion of a gate region at both sides adjacent to the bit line contact region. A second Si-based epitaxial layer is formed over the semiconductor substrate which is stepped up on the first Si-based epitaxial pattern. A stepped gate pattern is formed over the stepped second Si-based epitaxial layer.

Abstract: A pad oxide layer is formed on a substrate. A pad nitride layer is formed on the pad oxide layer. The pad nitride layer and the pad oxide layer are patterned. Predetermined portions of the substrate are etched using the pad nitride layer as an etch barrier to thereby form trenches used as device isolation regions. The trenches are filled with an insulation layer to thereby form device isolation regions. The pad nitride layer is removed. Recesses are formed by etching predetermined portions of the pad oxide layer and the substrate. The pad oxide layer is removed. A gate oxide layer is formed on the recesses and on the substrate. Gate structures of which bottom portions are buried in the recesses on the gate oxide layer are formed.

Abstract: A MOS transistor having a highly stressed channel region and a method for forming the same are provided. The method includes forming a first semiconductor plate over a semiconductor substrate, forming a second semiconductor plate on the first semiconductor plate wherein the first semiconductor plate has a substantially greater lattice constant than the second semiconductor plate, and forming a gate stack over the first and the second semiconductor plates. The first and the second semiconductor plates include extensions extending substantially beyond side edges of the gate stack. The method further includes forming a silicon-containing layer on the semiconductor substrate, preferably spaced apart from the first and the second semiconductor plates, forming a spacer, a LDD region and a source/drain region, and forming a silicide region and a contact etch stop layer. A high stress is developed in the channel region. Current crowding effects are reduced due to the raised silicide region.

Abstract: An integrated circuit is provided having a substrate and a transistor in an active region of the substrate. The substrate also has an isolation region having a dielectric material. In one embodiment, a pre-metal dielectric (PMD) layer is disposed over the substrate and the transistor. At least one of the isolation region or the PMD layer includes O3-TEOS having a first stress. A cap layer is disposed over the O3-TEOS in the isolation region or the PMD layer. The cap layer prevents degradation of the first stress of the O3-TEOS.

Abstract: The present invention provides a semiconductor device having a recess-structured ohmic electrode, in which the resistance is small and variation in the resistance value caused by manufacturing irregularities is small. In the semiconductor device of the present invention, a two-dimensional electron gas layer is formed on the interface between a channel-forming layer and a Schottky layer by electrons supplied from the Schottky layer. The ohmic electrode comprises a plurality of side faces in ohmic contact with the two-dimensional electron gas layer. At least a part of side faces of the ohmic electrodes are non-parallel to a channel width direction. In a preferred embodiment of the present invention, the side faces have a saw tooth form or a comb tooth form. Since the contact area between the ohmic electrode and the two-dimensional electron gas layer is increased, ohmic resistance is reduced.

Abstract: A NAND nonvolatile semiconductor memory device that has a memory cell array region and a selection gate region, has a semiconductor layer; a gate insulating film disposed on said semiconductor layer; a plurality of first electrode layers selectively disposed on said gate insulating film; a first device isolation insulating film formed in said memory cell array region and extends from between said adjacent first electrode layers into said semiconductor layer for device isolation; a second device isolation insulating film formed in said selection gate region and extends from between said adjacent first electrode layers into said semiconductor layer for device isolation; an interpoly insulating film formed at least on the top of said first electrode layers and said first device isolation insulating film in said memory cell array region; a second electrode layer disposed on said interpoly insulating film; and a third electrode layer disposed on said second electrode layer, said second device isolation insulating