Abstract: Image sensors are provided including a structure capable of settling an output voltage within a very short time for implementing a high-speed image sensor. The image sensor includes a pixel area, in which a photo-diode (PD) and a transfer transistor (Tr) configured to transmit charges accumulated in the PD to a floating diffusion (FD) area are disposed; and a Tr area, which is disposed adjacent to the pixel area and includes a first Tr, a second Tr, and a third Tr, wherein a first gate oxide film disposed below a first gate electrode of the first Tr and a second gate oxide film disposed below a second gate electrode of the second Tr include channel oxide films thinner than a gate oxide film of the transfer Tr.

Abstract: An etching method with a surface modification treatment for forming a semiconductor structure is provided. The method includes providing a semiconductor substrate, forming a silicon nitride (SiN) layer on the semiconductor substrate, and forming a silicon-containing layer on the semiconductor substrate and beside the SiN layer. The silicon-containing layer includes a silicon dioxide layer, a n-type silicon-containing layer, a p-type silicon-containing layer or a combination thereof. The method further includes performing a surface modification treatment onto the SiN layer and the silicon-containing layer by using a surface modification solution, thereby forming a modified layer on the SiN layer and the silicon-containing layer. The method further includes removing a portion of the modified layer and its underlying SiN layer by a wet etching operation, while the other portion of the modified layer and its underlying silicon-containing layer remain, and removing the other portion of the modified layer.

Abstract: A method for forming a high voltage transistor is provided. First, a substrate having a top surface is provided, following by forming a thermal oxide layer on the substrate. At least a part of the thermal oxidation layer is removed to form a recess in the substrate, wherein a bottom surface of the recess is lower than the top surface of the substrate. A gate oxide layer is formed in the recess, then a gate structure is formed on the gate oxide layer. The method further includes forming a source/drain region in the substrate.

Abstract: A method of reducing current leakage in three-dimensional semiconductor devices due to short-channel effects includes providing a starting semiconductor structure, the structure including a semiconductor substrate having a n-type device region and a p-type device region, the p-type device region including an upper layer of p-type semiconductor material, a hard mask layer over both regions, and a mask over the structure for patterning at least one fin in each region. The method further includes creating partial fin(s) in each region from the starting semiconductor structure, creating a conformal liner over the structure, creating a punch-through-stop (PTS) in each region, causing each PTS to diffuse across a top portion of the substrate, and creating full fin(s) in each region from the partial fin(s).

Abstract: A method for fabricated a buried recessed access device comprising etching a plurality of gate trenches in a substrate, implanting and activating a source/drain region in the substrate, depositing a dummy gate in each of the plurality of gate trenches, filling the plurality of gate trenches with an oxide layer, removing each dummy gate and depositing a high-K dielectric in the plurality of gate trenches, depositing a metal gate on the high-K dielectric in each of the plurality of gate trenches, depositing a second oxide layer on the metal gate and forming a contact on the source/drain.

Abstract: The invention includes methods of forming field effect transistors. In one implementation, the invention encompasses a method of forming a field effect transistor on a substrate, where the field effect transistor comprises a pair of conductively doped source/drain regions, a channel region received intermediate the pair of source/drain regions, and a transistor gate received operably proximate the channel region. Such implementation includes conducting a dopant activation anneal of the pair of source/drain regions prior to depositing material from which a conductive portion of the transistor gate is made. Other aspects and implementations are contemplated.

Abstract: A semiconductor device and a method for manufacturing the same are disclosed. A recess gate structure is formed between an overlapping region between a gate and a source/drain so as to suppress increase in gate induced drain leakage (GIDL), and a gate insulation film is more thickly deposited in a region having weak GIDL, thereby reducing GIDL and thus improving refresh characteristics due to leakage current.

Abstract: A method for fabricating a semiconductor device is provided, the method includes forming a plug conductive layer over an entire surface of a substrate, etching the plug conductive layer to form landing plugs, etching the substrate between the landing plugs to form a trench, forming a gate insulation layer over a surface of the trench and forming a buried gate partially filling the trench over the gate insulation layer.

Abstract: There is provided fin methods for fabricating fin structures. More specifically, fin structures are formed in a substrate. The fin structures may include two fins separated by a channel, wherein the fins may be employed as fins of a field effect transistor. The fin structures are formed below the upper surface of the substrate, and may be formed without utilizing a photolithographic mask to etch the fins.

Abstract: The present invention belongs to the technical field of semiconductor device manufacturing and specifically relates to a method for manufacturing a tunneling field effect transistor with a U-shaped channel. The U-shaped channel can effectively extend the transistor channel length, restrain the generation of leakage current in the transistor, and decrease the chip power consumption. The method for manufacturing a tunneling field effect transistor with a U-shaped channel put forward in the present invention is capable of realizing an extremely narrow U-shaped channel, overcoming the alignment deviation introduced by photoetching, and improving the chip integration degree.

Abstract: In a method of fabricating a semiconductor device having a MISFET of trench gate structure, a trench is formed from a major surface of a semiconductor layer of first conductivity type which serves as a drain region, in a depth direction of the direction of the semiconductor layer, a gate insulating film including a thermal oxide film and a deposited film is formed over the internal surface of the trench, and after a gate electrode has been formed in the trench, impurities are introduced into the semiconductor substrate of first conductivity type to form a semiconductor region of second conductivity type which serves as a channel forming region, and impurities are introduced into the semiconductor region of second conductivity type to form the semiconductor region of first conductivity type which serves as a source region.

Abstract: In various embodiments, a semiconductor device is provided. The semiconductor device may include a first source/drain region, a second source/drain region, an active region electrically coupled between the first source/drain region and the second source/drain region, a trench disposed between the second source/drain region and at least a portion of the active region, a first isolation layer disposed over the bottom and the sidewalls of the trench, electrically conductive material disposed over the isolation layer in the trench, a second isolation layer disposed over the active region, and a gate region disposed over the second isolation layer. The electrically conductive material may be coupled to an electrical contact.

Abstract: A replacement metal gate structure and methods of manufacturing the same is provided. The method includes forming at least one trench structure and forming a liner of high-k dielectric material in the at least one trench structure. The method further includes adjusting a height of the liner of high-k dielectric material. The method further includes forming at least one workfunction metal over the liner, and forming a metal gate structure in the at least one trench structure, over the at least one workfunction metal and the liner of high-k dielectric material.

Abstract: A semiconductor device including a buried gate and a method for forming the same are disclosed. The semiconductor device includes a buffer layer formed on a surface of a trench in a semiconductor substrate, and a gate electrode configured to partially bury the trench and formed of the same material as in the buffer layer.

Abstract: A semiconductor device includes a transistor that has a trench formed in an element forming region of a substrate, a gate insulating film formed on side faces and a bottom face of the trench, a gate electrode formed on the gate insulating film so as to bury the trench, a source region formed on one side in the gate longitude direction, which is formed on the surface of the substrate, and a drain region formed on the other side in the gate longitude direction. Here, the gate electrode is formed so as to be exposed also on the substrate outside the trench, and the gate electrode is disposed so as to cover upper portions of both ends of the trench and so as to form at least one concave portion having a depth reaching the substrate in a center portion.

Abstract: A method of fabricating a semiconductor device can include forming a trench in a semiconductor substrate, forming a first conductive layer on a bottom surface and side surfaces of the trench, and selectively forming a second conductive layer on the first conductive layer to be buried in the trench. The second conductive layer may be formed selectively on the first conductive layer by using an electroless plating method or using a metal organic chemical vapor deposition (MOCVD) or an atomic layer deposition (ALD) method.

Abstract: The invention includes methods of forming field effect transistors. In one implementation, the invention encompasses a method of forming a field effect transistor on a substrate, where the field effect transistor comprises a pair of conductively doped source/drain regions, a channel region received intermediate the pair of source/drain regions, and a transistor gate received operably proximate the channel region. Such implementation includes conducting a dopant activation anneal of the pair of source/drain regions prior to depositing material from which a conductive portion of the transistor gate is made. Other aspects and implementations are contemplated.

Abstract: Vertical field effect transistor semiconductor structures and methods for fabrication of the vertical field effect transistor semiconductor structures provide an array of semiconductor pillars. Each vertical portion of each semiconductor pillar in the array of semiconductor pillars has a linewidth greater than a separation distance to an adjacent semiconductor pillar. Alternatively, the array may comprise semiconductor pillars with different linewidths, optionally within the context of the foregoing linewidth and separation distance limitations. A method for fabricating the array of semiconductor pillars uses a minimally photolithographically dimensioned pillar mask layer that is annularly augmented with at least one spacer layer prior to being used as an etch mask.

Abstract: In Trench-Gate Fin-FET, in order that the advantage which is exerted in Fin-FET can be sufficiently taken even if a transistor becomes finer and, at the same time, decreasing of on-current can be suppressed by saving a sufficiently large contact area in the active region, a fin width 162 of a channel region becomes smaller than a width 161 of an active region.

Abstract: A method for fabricating a semiconductor device is provided, the method includes forming a plug conductive layer over an entire surface of a substrate, etching the plug conductive layer to form landing plugs, etching the substrate between the landing plugs to form a trench, forming a gate insulation layer over a surface of the trench and forming a buried gate partially filling the trench over the gate insulation layer.

Abstract: While embedded silicon germanium alloy and silicon carbon alloy provide many useful applications, especially for enhancing the mobility of MOSFETs through stress engineering, formation of alloyed silicide on these surfaces degrades device performance. The present invention provides structures and methods for providing unalloyed silicide on such silicon alloy surfaces placed on semiconductor substrates. This enables the formation of low resistance contacts for both mobility enhanced PFETs with embedded SiGe and mobility enhanced NFETs with embedded Si:C on the same semiconductor substrate. Furthermore, this invention provides methods for thick epitaxial silicon alloy, especially thick epitaxial Si:C alloy, above the level of the gate dielectric to increase the stress on the channel on the transistor devices.

Abstract: A method of fabricating a semiconductor device, the method includes forming gate patterns on a substrate, recessing the substrate between the gate patterns, thereby forming a first resulting structure including recesses, forming a gate spacer layer on an entire surface of the first resulting structure including the gate patterns, etching the gate spacer layer at a bottom of the recess, and forming a plug on the recess, thereby forming a second resulting structure including the plug.

Abstract: A semiconductor device including: a SiC substrate; an AlGaN layer formed on the SiC substrate; a source electrode and a drain electrode formed on the AlGaN layer so as to be spaced from each other; an insulation film formed between the source electrode and the drain electrode and having a band-like opening in parallel to the source electrode and the drain electrode; a gate electrode formed at the opening in the insulation film; and a drain-side field plate electrode formed integrally with the gate electrode on the drain electrode side of the gate electrode and having a drain electrode side end portion spaced from the insulation film, thus restraining degradation in performance.

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 transistor and method of fabricating the transistor are disclosed. The transistor is disposed in an active region of a substrate defined by an isolation region and includes a gate electrode and associated source/drain regions. The isolation region includes an upper isolation region and an lower isolation region, wherein the upper isolation region is formed with sidewalls having, at least in part, a positive profile.

Abstract: Provided is a method of fabricating a semiconductor device having a transistor. The method includes forming a first gate trench in a first active region of a semiconductor substrate. A first gate layer partially filling the first gate trench is formed. Ions may be implanted in the first gate layer and in the first active region on both sides of the first gate layer such that the first gate layer becomes a first gate electrode of a first conductivity type and first impurity regions of the first conductivity type are formed on both sides of the first gate electrode.

Abstract: A metal member layer on a silicon member layer is patterned. A sidewall film is formed on a surface of the metal member layer. The silicon member layer is patterned to form a structure including the silicon member layer and the metal member layer, the surface of which is covered with the sidewall film. After the surface of the structure is cleaned, a water-repellent protective film is formed on the surface of the structure before the surface of the structure is dried.

Abstract: A method for forming a field effect transistor with an active area and a termination region surrounding the active area includes forming a well region in a first silicon region, where the well region and the first silicon region are of opposite conductivity type. Gate trenches extending through the well region and terminating within the first silicon region are formed. A recessed gate is formed in each gate trench. A dielectric cap is formed over each recessed gate. The well region is recessed between adjacent trenches to expose upper sidewalls of each dielectric cap. A blanket source implant is carried out to form a second silicon region in an upper portion of the recessed well region between every two adjacent trenches. A dielectric spacer is formed along each exposed upper sidewall of the dielectric cap, with every two adjacent dielectric spacers located between every two adjacent gate trenches forming an opening over the second silicon region.

Abstract: In a method of fabricating a semiconductor device having a MISFET of trench gate structure, a trench is formed from a major surface of a semiconductor layer of first conductivity type which serves as a drain region, in a depth direction of the semiconductor layer, a gate insulating film including a thermal oxide film and a deposited film is formed over the internal surface of the trench, and after a gate electrode has been formed in the trench, impurities are introduced into the semiconductor substrate of first conductivity type to form a semiconductor region of second conductivity type which serves as a channel forming region, and impurities are introduced into the semiconductor region of second conductivity type to form the semiconductor region of first conductivity type which serves as a source region.

Abstract: This invention discloses a trenched metal oxide semiconductor field effect transistor (MOSFET) cell. The trenched MOSFET cell includes a trenched gate opened from a top surface of the semiconductor substrate surrounded by a source region encompassed in a body region above a drain region disposed on a bottom surface of a substrate. The trenched gate further includes at least two mutually insulated trench-filling segments each filled with materials of different work functions. In an exemplary embodiment, the trenched gate includes a polysilicon segment at a bottom portion of the trenched gate and a metal segment at a top portion of the trenched gate.

Abstract: A field-effect transistor and a method for manufacturing a field-effect transistor is disclosed. One embodiment includes a substrate having a surface along which a trench is implemented, wherein the trench has a trench bottom and a trench edge. A source area is implemented at the trench edge and a gate electrode at least partially implemented in the trench and separated from the substrate by an insulation layer. The field-effect transistor includes a drain electrode at a side of the substrate facing away from the surface. An additional electrode is implemented between the gate electrode and the trench bottom and electrically insulated from the substrate and an electrical connection between the additional electrode and the gate electrode, wherein the electrical connection has a predetermined ohmic resistance value.

Abstract: A recess gate of a semiconductor device is provided, comprising: a substrate having a recess formed therein; a metal layer formed at the bottom of the recess; a polysilicon layer formed over the metal layer; and a source region and a drain region formed adjacent to the polysilicon layer and spaced from the metal layer.

Abstract: The present invention relates to a semiconductor device that includes a semiconductor substrate (10) having source/drain diffusion regions (14) formed therein and control gates (20) formed thereon, with grooves (18) being formed on the surface of the semiconductor substrate (10) and being located below the control gates (20) and between the source/drain diffusion regions (14). The grooves (18) are separated from the source/drain diffusion regions (14), thereby increasing the effective channel length to maintain a constant channel length for charge accumulation while enabling the manufacture of smaller memory cells. The present invention also provides a method of manufacturing the semiconductor device.

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: A semiconductor device includes a device isolation structure having a grounded conductive layer to define an active region, and a gate formed over the active region and the device isolation structure.

Abstract: Provided is a method of fabricating a semiconductor device having an impurity region with an impurity concentration of a first dose in a substrate. In the method, first impurity ions of a first conductivity type are implanted into the substrate, and a rapid thermal processing (RTP) is performed on the substrate to activate the first impurity ions. Second impurity ions of the first conductivity type are implanted into the substrate having the activated first impurity ions.

Abstract: A number of methods are provided for semiconductor processing. One such method includes depositing a first precursor material on a surface at a particular temperature to form an undoped polysilicon. The method also includes depositing a second precursor material on a surface of the undoped polysilicon at substantially the same temperature, wherein the undoped polysilicon serves as a seed to accelerate forming a doped polysilicon.

Abstract: A transistor and method of fabricating the transistor are disclosed. The transistor is disposed in an active region of a substrate defined by an isolation region and includes a gate electrode and associated source/drain regions. The isolation region includes an upper isolation region and an lower isolation region, wherein the upper isolation region is formed with sidewalls having, at least in part, a positive profile.

Abstract: There is provided a method for manufacturing a semiconductor device having a high breakdown voltage transistor and a low breakdown voltage transistor provided on a same semiconductor substrate.

Abstract: Unit cells of metal oxide semiconductor (MOS) transistors are provided having an integrated circuit substrate and a MOS transistor on the integrated circuit substrate. The MOS transistor includes a source region, a drain region and a gate. The gate is between the source region and the drain region. A channel region is provided between the source and drain regions. The channel region has a recessed region that is lower than bottom surfaces of the source and drain regions. Related methods of fabricating transistors are also provided.

Abstract: The invention includes methods of forming field effect transistors. In one implementation, the invention encompasses a method of forming a field effect transistor on a substrate, where the field effect transistor comprises a pair of conductively doped source/drain regions, a channel region received intermediate the pair of source/drain regions, and a transistor gate received operably proximate the channel region. Such implementation includes conducting a dopant activation anneal of the pair of source/drain regions prior to depositing material from which a conductive portion of the transistor gate is made. Other aspects and implementations are contemplated.

Abstract: Wider and narrower trenches are formed in a substrate. A first gate material layer is deposited but not fully fills the wider trench. The first gate material layer in the wider trench and above the substrate original surface is removed by isotropic or anisotropic etching back. A first dopant layer is formed in the surface layer of the substrate at the original surface and the sidewall and bottom of the wider trench by tilt ion implantation. A second gate material layer is deposited to fully fill the trenches. The gate material layer above the original surface is removed by anisotropic etching back. A second dopant layer is formed in the surface layer of the substrate at the original surface by ion implantation. The dopants are driven-in to form a base in the substrate and a bottom-lightly-doped layer surrounding the bottom of the wider trench and adjacent to the base.

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: In a method of manufacturing a semiconductor device, a trench is formed to have an upper quadrangular section and a lower circular section which is formed through a hydrogen annealing process, to extend in a depth direction of a semiconductor substrate. An insulating film is formed on a surface of the trench and a surface of the semiconductor substrate. A conductive film is formed to fill the trench whose surface is covered with the an insulating film. Source/drain regions are formed on both sides of the trench.

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: A semiconductor structure including a substrate, a gate dielectric layer, a gate, a source region and a drain region is provided. The gate dielectric layer is disposed on the substrate. At least one recess is disposed in the substrate. The gate is disposed on the gate dielectric layer and in the recess. The source and drain regions are respectively disposed in the substrate beside the gate.

Abstract: A semiconductor apparatus including a trench gate transistor having at least an active region surrounded by a device isolation insulating film; a trench provided by bringing both ends thereof into contact with the device isolation insulating film in the active region; a gate electrode formed in the trench via a gate insulating film; and a diffusion layer formed close to the trench; on a semiconductor substrate, and also includes an opening portion positioned on one surface of the semiconductor substrate; a pair of first inner walls positioned in a side of the device isolation insulating film and connected with the opening portion; a pair of second inner walls positioned in a side of the active region and connected with the opening portion; and a bottom portion positioned opposite to the opening portion and connected with the first inner walls and the second inner walls, wherein a cross sectional outline of the second inner wall is substantially linear, and a burr generated inside the trench is removed or redu

Abstract: Forming a high-?/metal gate field effect transistor using a gate last process in which the channel region has a curved profile thus increasing the effective channel length improves the short channel effect. During the high-?/metal gate process, after the sacrificial materials between the sidewall spacers are removed, the exposed semiconductor substrate surface at the bottom of the gate trench cavity is etched to form a curved recess. Subsequent deposition of high-? gate dielectric layer and gate electrode metal into the gate trench cavity completes the high-?/metal gate field effect transistor having a curved channel region that has a longer effective channel length.

Abstract: A method for forming a semiconductor device having recess channel includes forming a hard mask film pattern for exposing first regions for forming the trenches on a semiconductor substrate; forming first trenches by a first etching process using the hard mask film pattern as a mask, and removing the hard mask film pattern; forming a barrier film on the semiconductor substrate including the first trenches; forming an ion implantation mask film for exposing the first trenches on the barrier film; forming an ion implantation region in the semiconductor substrate below the first trenches using the ion implantation mask film and the barrier film; forming bulb-shaped second trenches by a second etching process using the ion implantation mask film and the barrier film as a mask, so that bulb-type trenches for recess channels, each including the first trench and the second trench, are formed; and removing the ion implantation mask film and the barrier film.

Abstract: A method for manufacturing a semiconductor device includes the steps of: forming a trench in a semiconductor substrate; and forming an epitaxial film on the substrate including a sidewall and a bottom of the trench so that the epitaxial film is filled in the trench. The step of forming the epitaxial film includes a final step before the trench is filled with the epitaxial film. The final step has a forming condition of the epitaxial film in such a manner that the epitaxial film to be formed on the sidewall of the trench has a growth rate at an opening of the trench smaller than a growth rate at a position of the trench, which is deeper than the opening of the trench.