Abstract: A field effect transistor includes a partial SiGe channel, i.e., a channel including a SiGe channel portion, located underneath a gate electrode and a Si channel portion located underneath an edge of the gate electrode near the drain region. The SiGe channel portion can be located directly underneath a gate dielectric, or can be located underneath a Si channel layer located directly underneath a gate dielectric. The Si channel portion is located at the same depth as the SiGe channel portion, and contacts the drain region of the transistor. By providing a Si channel portion near the drain region, the GIDL current of the transistor is maintained at a level on par with the GIDL current of a transistor having a silicon channel only during an off state.

Abstract: In a semiconductor capable of reducing NBTI and a method for manufacturing the same, a multi-gate transistor includes an active region, gate dielectric, channels in the active region, and gate electrodes, and is formed on a semiconductor wafer. The active region has a top and side surfaces, and is oriented in a first direction. The gate dielectric is formed on the top and side surfaces of the active region. The channels are formed in the top and side surfaces of the active region. The gate electrodes are formed on the gate dielectric corresponding to the channels and aligned perpendicular to the active region such that current flows in the first direction. In one aspect of the invention, an SOI layer having a second orientation indicator in a second direction is formed on a supporting substrate having a first orientation indicator in a first direction.

Abstract: In a semiconductor capable of reducing NBTI and a method for manufacturing the same, a multi-gate transistor includes an active region, gate dielectric, channels in the active region, and gate electrodes, and is formed on a semiconductor wafer. The active region has a top and side surfaces, and is oriented in a first direction. The gate dielectric is formed on the top and side surfaces of the active region. The channels are formed in the top and side surfaces of the active region. The gate electrodes are formed on the gate dielectric corresponding to the channels and aligned perpendicular to the active region such that current flows in the first direction. In one aspect of the invention, an SOI layer having a second orientation indicator in a second direction is formed on a supporting substrate having a first orientation indicator in a first direction.

Abstract: A semiconductor structure and a method for fabricating the semiconductor structure include a hybrid orientation substrate having a first active region having a first crystallographic orientation that is vertically separated from a second active region having a second crystallographic orientation different than the first crystallographic orientation. A first field effect device having a first gate electrode is located and formed within and upon the first active region and a second field effect device having a second gate electrode is located and formed within and upon the second active region. Upper surfaces of the first gate electrode and the second gate electrode are coplanar. The structure and method allow for avoidance of epitaxial defects generally encountered when using hybrid orientation technology substrates that include coplanar active regions.

Abstract: A semiconductor structure having: a silicon substrate having a crystallographic orientation; an insulating layer disposed over the silicon substrate; a silicon layer having a different crystallographic orientation than the crystallographic orientation of the substrate disposed over the insulating layer; and a column III-V transistor device having the same crystallographic orientation as the substrate disposed on the silicon substrate. In one embodiment, the column III-V transistor device is in contact with the substrate. In one embodiment, the device is a GaN device. In one embodiment, the crystallographic orientation of the substrate is <111> and wherein the crystallographic orientation of the silicon layer is <100>. In one embodiment, CMOS transistors are disposed in the silicon layer. In one embodiment, the column III-V transistor device is a column III-N device. In one embodiment, a column III-As, III-P, or III-Sb device is disposed on the top of the <100> silicon layer.

Abstract: In a transistor, a strain-inducing semiconductor alloy, such as silicon/germanium, silicon/carbon and the like, may be positioned very close to the channel region by providing gradually shaped cavities which may then be filled with the strain-inducing semiconductor alloy. For this purpose, two or more “disposable” spacer elements of different etch behavior may be used in order to define different lateral offsets at different depths of the corresponding cavities. Consequently, enhanced uniformity and, thus, reduced transistor variability may be accomplished, even for sophisticated semiconductor devices.

Abstract: An accumulation mode transistor has an impurity concentration of a semiconductor layer in a channel region at a value higher than 2×1017 cm?3 to achieve a large gate voltage swing.

Abstract: The present application discloses a semiconductor device and a method of manufacturing the same. Wherein, the semiconductor device comprises: a semiconductor substrate; a stressor embedded in the semiconductor substrate; a channel region disposed on the stressor; a gate stack disposed on the channel region; a source/drain region disposed on two sides of the channel region and embedded in the semiconductor substrate; wherein, surfaces of the stressor comprise a top wall, a bottom wall, and side walls, the side walls comprising a first side wall and a second side wall, the first side wall connecting the top wall and the second side wall, the second side wall connecting the first side wall and the bottom wall, the angle between the first side wall and the second side wall being less than 180°, and the first sidewall and the second side wall being roughly symmetrical with respect to a plane parallel to the semiconductor substrate.

Abstract: A method for manufacturing multi-gate transistor devices includes providing a semiconductor substrate having a first patterned hard mask for defining at least a first fin formed thereon, forming the first fin having a first crystal plane orientation on the semiconductor substrate, forming a second patterned hard mask for defining at least a second fin on the semiconductor substrate, forming the second fin having a second crystal plane orientation that is different from the first crystal plane orientation on the semiconductor substrate, forming a gate dielectric layer and a gate layer covering a portion of the first fin and a portion of the second fin on the semiconductor substrate, and forming a first source/drain in the first fin and a second source/drain in the second fin, respectively.

Abstract: In contrast to a conventional planar CMOS technique in design and fabrication for a field-effect transistor (FET), the present invention provides an SGT CMOS device formed on a conventional substrate using various crystal planes in association with a channel type and a pillar shape of an FET, without a need for a complicated device fabrication process. Further, differently from a design technique of changing a surface orientation in each planar FET, the present invention is designed to change a surface orientation in each SGT to achieve improvement in carrier mobility. Thus, a plurality of SGTs having various crystal planes can be formed on a common substrate to achieve a plurality of different carrier mobilities so as to obtain desired performance.

Abstract: The embodiments of methods and structures are for doping fin structures by plasma doping processes to enable formation of shallow lightly doped source and drain (LDD) regions. The methods involve a two-step plasma doping process. The first step plasma process uses a heavy carrier gas, such as a carrier gas with an atomic weight equal to or greater than about 20 amu, to make the surfaces of fin structures amorphous and to reduce the dependence of doping rate on crystalline orientation. The second step plasma process uses a lighter carrier gas, which is lighter than the carrier gas for the first step plasma process, to drive the dopants deeper into the fin structures. The two-step plasma doping process produces uniform dopant profile beneath the outer surfaces of the fin structures.

Abstract: The invention provides a semiconductor device comprising: a substrate; a gate, which is formed on the substrate; a source and a drain, which are located on opposite sides of the gate, respectively; a contact, which contacts with the source and/or the drain, wherein the contact has an enlarged end at an end which is in contact with the source and/or the drain. In the present invention, since the contact area of the contact is increased on the interface in contact with the source/the drain, the contact resistance can be reduced, and thus the performances of the semiconductor device can be guaranteed/improved. The present invention further provides a method of fabricating the semiconductor device (especially the contact therein) as previously described.

Abstract: In a semiconductor capable of reducing NBTI and a method for manufacturing the same, a multi-gate transistor includes an active region, gate dielectric, channels in the active region, and gate electrodes, and is formed on a semiconductor wafer. The active region has a top and side surfaces, and is oriented in a first direction. The gate dielectric is formed on the top and side surfaces of the active region. The channels are formed in the top and side surfaces of the active region. The gate electrodes are formed on the gate dielectric corresponding to the channels and aligned perpendicular to the active region such that current flows in the first direction. In one aspect of the invention, an SOI layer having a second orientation indicator in a second direction is formed on a supporting substrate having a first orientation indicator in a first direction. A multi-gate transistor is formed on the SOI layer.

Abstract: A vertical semiconductor device includes a bottom metal layer and a first P-type semiconductor layer overlying the bottom metal layer. The first P-type semiconductor layer is characterized by a surface crystal orientation of (110) and a first conductivity. The first P-type semiconductor layer is heavily doped. The vertical semiconductor device also includes a second P-type semiconductor layer overlying the first P-type semiconductor layer. The second semiconductor layer has a surface crystal orientation of (110) and is characterized by a lower conductivity than the first conductivity. The vertical semiconductor device also has a top metal layer overlying the second P-type semiconductor layer. A current conduction from the top metal layer to the bottom metal layer and through the second p-type semiconductor layer is characterized by a hole mobility along a <110> crystalline orientation and on (110) crystalline plane.

Abstract: A channel is formed at a recessed portion or a projecting portion of a substrate, and a gate insulating film is formed so as to have first to third insulating regions along the channel. Each of the gate insulating films of the first and third insulating regions has a first gate insulating film containing no electric charge trap formed on a plane different from a principal surface of the substrate, an electric charge accumulating film containing an electric charge trap, and a second gate insulating film containing no electric charge trap. The gate insulating film of the second insulating region at the middle is formed on a plane parallel to the principal surface of the substrate and is composed of only a third gate insulating film containing no electric charge trap.

Abstract: Semiconductor transistor devices and related fabrication methods are provided. An exemplary transistor device includes a layer of semiconductor material having a channel region defined therein and a gate structure overlying the channel region. Recesses are formed in the layer of semiconductor material adjacent to the channel region, such that the recesses extend asymmetrically toward the channel region. The transistor device also includes stress-inducing semiconductor material formed in the recesses. The asymmetric profile of the stress-inducing semiconductor material enhances carrier mobility in a manner that does not exacerbate the short channel effect.

Abstract: A semiconductor structure comprises a substrate, a gate structure, at least a source/drain region, a recess and an epitaxial layer. The substrate includes an up surface. A gate structure is located on the upper surface. The source/drain region is located within the substrate beside the gate structure. The recess is located within the source/drain region. The epitaxial layer fills the recess, and the cross-sectional profile of the epitaxial layer is an octagon.

Abstract: An accumulation mode transistor has an impurity concentration of a semiconductor layer in a channel region at a value higher than 2×1017 cm?3 to achieve a large gate voltage swing.

Abstract: A semiconductor device with stress trench isolation and a method for forming the same are provided. The method includes: providing a silicon substrate; forming first trenches and second trenches on the silicon substrate, wherein an extension direction of the first trenches is perpendicular to that of the second trenches; forming a first dielectric layer in the first trenches and forming a second dielectric layer in the second trenches; and forming a gate stack on a portion of the silicon substrate surrounded by the first trenches and the second trenches, wherein a channel length direction under the gate stack is parallel to the extension direction of the first trenches, indices of crystal plane of the silicon substrate are {100}, and the extension direction of the first trenches is along the crystal orientation <110>. The embodiments of the present invention can improve response speed and performance of the devices.

Abstract: An integrated circuit (IC) includes a fin field effect transistor (FinFET) radio frequency (RF) switch; and a planar complementary metal-oxide semiconductor field effect transistor (MOSFET). The planar MOSFET has a channel on a <100> wafer plane and the FinFET RF switch has a channel on a <100> fin plane. The FinFET RF switch and the planar MOSFET can be oriented at approximately 45° with respect to one another.

Abstract: Novel articles and methods to fabricate same with self-assembled nanodots and/or nanorods of a single or multicomponent material within another single or multicomponent material for use in electrical, electronic, magnetic, electromagnetic and electrooptical devices is disclosed. Self-assembled nanodots and/or nanorods are ordered arrays wherein ordering occurs due to strain minimization during growth of the materials. A simple method to accomplish this when depositing in-situ films is also disclosed. Device applications of resulting materials are in areas of superconductivity, photovoltaics, ferroelectrics, magnetoresistance, high density storage, solid state lighting, non-volatile memory, photoluminescence, thermoelectrics and in quantum dot lasers.

Abstract: A method of patterning a semiconductor film is described. According to an embodiment of the present invention, a hard mask material is formed on a silicon film having a global crystal orientation wherein the semiconductor film has a first crystal plane and second crystal plane, wherein the first crystal plane is denser than the second crystal plane and wherein the hard mask is formed on the second crystal plane. Next, the hard mask and semiconductor film are patterned into a hard mask covered semiconductor structure. The hard mask covered semiconductor structured is then exposed to a wet etch process which has sufficient chemical strength to etch the second crystal plane but insufficient chemical strength to etch the first crystal plane.

Abstract: An object is to realize high performance and low power consumption in a semiconductor device having an SOI structure. In addition, another object is to provide a semiconductor device having a high performance semiconductor element which is more highly integrated. A semiconductor device is such that a plurality of n-channel field-effect transistors and p-channel field-effect transistors are stacked with an interlayer insulating layer interposed therebetween over a substrate having an insulating surface. By controlling a distortion caused to a semiconductor layer due to an insulating film having a stress, a plane orientation of the semiconductor layer, and a crystal axis in a channel length direction, difference in mobility between the n-channel field-effect transistor and the p-channel field-effect transistor can be reduced, whereby current driving capabilities and response speeds of the n-channel field-effect transistor and the p-channel field-effect can be comparable.

Abstract: Provided is a semiconductor device including: source-drain regions formed on a silicon substrate with a channel forming region sandwiched therebetween; a word gate electrode formed on the channel forming region via a word gate insulating film not including a charge storage layer; a control gate formed on the silicon substrate on one side of the word gate electrode via a trap insulating film including a charge storage layer; and a control gate formed on the silicon substrate on the other side of the word gate electrode via a trap insulating film including a charge storage layer. A bottom of the word gate electrode is made to be higher than the control gate and a bottom of the control gate, and a level difference between the bottoms of the electrodes is made to be larger than a physical film thickness of the word gate insulating film.

Abstract: A high breakdown voltage circuit containing a high breakdown voltage MOSFET in LSI, unlike a quintessential internal circuit, has an operating voltage fixed in a high state due to the relation with the outside and, therefore, miniaturization by the voltage lowering can not be applied, differing from ordinary cases. Consequently, the voltage lowering of an internal circuit part results in a furthermore enlargement of occupying area in the chip. The present inventors evaluated various measures for the problem, and made it clear that such problems as compatibility with the CMOSFET circuit configuration and device configuration, etc. constitute obstacles.

Abstract: A device includes a semiconductor substrate, and insulation regions in the semiconductor substrate. Opposite sidewalls of the insulation regions have a spacing between about 70 nm and about 300 nm. A III-V compound semiconductor region is formed between the opposite sidewalls of the insulation regions.

Abstract: An integrated circuit device and method for manufacturing the integrated circuit device is disclosed. The disclosed method provides improved control over a surface proximity and tip depth of integrated circuit device. In an embodiment, the method achieves improved control by forming a lightly doped source and drain (LDD) region that acts as an etch stop. The LDD region may act as an etch stop during an etching process implemented to form a recess in the substrate that defines a source and drain region of the device.

Abstract: Apparatus for semiconductor device structures and related fabrication methods are provided. One method for fabricating a semiconductor device structure involves forming a gate structure overlying a region of semiconductor material, wherein the width of the gate structure is aligned with a <100> crystal direction of the semiconductor material. The method continues by forming recesses about the gate structure and forming a stress-inducing semiconductor material in the recesses.

Abstract: A GAA (Gate-All-Around) CMOSFET device includes a semiconductor substrate, a PMOS region having a first channel, an NMOS region having a second channel and a gate region. The surfaces of the first channel and the second channel are substantially surrounded by the gate region. A buried insulation layer is disposed between the PMOS region and the NMOS region and between the PMOS or NMOS region and the semiconductor substrate to isolate them from one another. The structure is simple, compact and highly integrated, has high carrier mobility, and avoids polysilicon gate depletion and short channel effect.

Abstract: By appropriately orienting the channel length direction with respect to the crystallographic characteristics of the silicon layer, the stress-inducing effects of strained silicon/carbon material may be significantly enhanced compared to conventional techniques. In one illustrative embodiment, the channel may be oriented along the <100> direction for a (100) surface orientation, thereby providing an electron mobility increase of approximately a factor of four.

Abstract: A method of forming a field effect transistor having a heavily doped p-type (110) semiconductor layer over a metal substrate starts with providing a heavily doped p-type (110) silicon layer, and forming a lightly doped p-type (110) silicon layer on the P heavily doped-type (110) silicon layer. The method also includes forming a p-channel MOSFET which has a channel region along a (110) crystalline plane in the lightly doped p-type (110) silicon layer to allow a current conduction in a <110> direction. The p-channel MOSFET also includes a gate dielectric layer having a high dielectric constant material lining the (110) crystalline plane. The method further includes forming a top conductor layer overlying the lightly doped p-type (110) silicon layer and a bottom conductor layer underlying the heavily doped p-type (110) silicon layer.

Abstract: A semiconductor structure including a bi-layer nFET embedded stressor element is disclosed. The bi-layer nFET embedded stressor element can be integrated into any CMOS process flow. The bi-layer nFET embedded stressor element includes an implant damaged free first layer of a first epitaxy semiconductor material having a lattice constant that is different from a lattice constant of a semiconductor substrate and imparts a tensile strain in a device channel of an nFET gate stack. Typically, and when the semiconductor is composed of silicon, the first layer of the bi-layer nFET embedded stressor element is composed of Si:C. The bi-layer nFET embedded stressor element further includes a second layer of a second epitaxy semiconductor material that has a lower resistance to dopant diffusion than the first epitaxy semiconductor material. Typically, and when the semiconductor is composed of silicon, the second layer of the bi-layer nFET embedded stressor element is composed of silicon.

Abstract: A semiconductor structure and method of fabricating the structure. The method includes removing the backside silicon from two silicon-on-insulator wafers having devices fabricated therein and bonding them back to back utilizing the buried oxide layers. Contacts are then formed in the upper wafer to devices in the lower wafer and wiring levels are formed on the upper wafer. The lower wafer may include wiring levels. The lower wafer may include landing pads for the contacts. Contacts to the silicon layer of the lower wafer may be silicided.

Abstract: Provided are a biosensor with a silicon nanowire and a method of manufacturing the same, and more particularly, a biosensor with a silicon nanowire including a defect region formed by irradiation of an electron beam, and a method of manufacturing the same. The biosensor includes: a silicon substrate; a source region disposed on the silicon substrate; a drain region disposed on the silicon substrate; and a silicon nanowire disposed on the source region and the drain region, and having a defect region formed by irradiation of an electron beam. Therefore, by irradiating a certain region of a high-concentration doped silicon nanowire with an electron beam to lower electron mobility in the certain region, it is possible to maintain a low contact resistance between the silicon nanowire and a metal electrode and to lower operation current of a biomaterial detection part, thereby improving sensitivity of the biosensor.

Abstract: A method of manufacturing a semiconductor device, including the steps of preparing a silicon substrate which has a main surface whose plane direction is a surface (100); forming an n channel MISFET (Metal Insulator Semiconductor Field Effect Transistor) which has a gate electrode, a source region, a drain region and a channel whose channel length direction is parallel to a crystal orientation <100> of the silicon substrate; and forming NiSi over the gate electrode and NiSi2 over the source region and the drain region at the same steps.

Abstract: A semiconductor memory structure with stress regions includes a substrate defining a first and a second device zone; a first and a second stress region formed in each of the first and second device zone to yield stress different in level; a barrier plug separating the two device zones from each other; and a plurality of oxide spacers being located between the first stress regions and the barrier plug while in direct contact with the first stress regions. Due to the stress yielded at the stress regions, increased carrier mobility and accordingly, increased reading current can be obtained, and only a relatively lower reading voltage is needed to obtain an initially required reading current. As a result, the probability of stress-induced leakage current is reduced to enhance the data retention ability.

Abstract: The present invention discloses the use of edge-angle-optimized solid phase epitaxy for forming hybrid orientation substrates comprising changed-orientation Si device regions free of the trench-edge defects typically seen when trench-isolated regions of Si are recrystallized to the orientation of an underlying single-crystal Si template after an amorphization step. For the case of amorphized Si regions recrystallizing to (100) surface orientation, the trench-edge-defect-free recrystallization of edge-angle-optimized solid phase epitaxy may be achieved in rectilinear Si device regions whose edges align with the (100) crystal's in-plane <100> directions.

Abstract: A FinFET device and method for fabricating a FinFET device is disclosed. An exemplary FinFET device includes a substrate of a crystalline semiconductor material having a top surface of a first crystal plane orientation; a fin structure of the crystalline semiconductor material overlying the substrate; a gate structure over a portion of the fin structure; an epitaxy layer over another portion of the fin structure, the epitaxy layer having a surface having a second crystal plane orientation, wherein the epitaxy layer and underlying fin structure include a source and drain region, the source region being separated from the drain region by the gate structure; and a channel defined in the fin structure from the source region to the drain region, and aligned in a direction parallel to both the surface of the epitaxy layer and the top surface of the substrate.

Abstract: A semiconductor structure having: a silicon substrate having a crystallographic orientation; an insulating layer disposed over the silicon substrate; a silicon layer having a different crystallographic orientation than the crystallographic orientation of the substrate disposed over the insulating layer; and a column III-V transistor device having the same crystallographic orientation as the substrate disposed on the silicon substrate. In one embodiment, the column III-V transistor device is in contact with the substrate. In one embodiment, the device is a GaN device. In one embodiment, the crystallographic orientation of the substrate is <111> and wherein the crystallographic orientation of the silicon layer is <100>. In one embodiment, CMOS transistors are disposed in the silicon layer. In one embodiment, the column III-V transistor device is a column III-N device. In one embodiment, a column III-As, III-P, or III-Sb device is disposed on the top of the <100> silicon layer.

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

Abstract: It is an object to achieve high performance of a semiconductor integrated circuit depending on not only a microfabrication technique but also another way and to achieve low power consumption of a semiconductor integrated circuit. A semiconductor device is provided in which a crystal orientation or a crystal axis of a single-crystalline semiconductor layer for a MISFET having a first conductivity type is different from that of a single-crystalline semiconductor layer for a MISFET having a second conductivity type. A crystal orientation or a crystal axis is such that mobility of carriers traveling in a channel length direction is increased in each MISFET. With such a structure, mobility of carriers flowing in a channel of a MISFET is increased, and a semiconductor integrated circuit can be operated at higher speed. Further, low voltage driving becomes possible, and low power consumption can be achieved.

Abstract: A semiconductor device, including a device isolation layer arranged on a predetermined region of a semiconductor substrate to define an active region, the active region including a central top surface of a (100) crystal plane and an inclined edge surface extending from the central top surface to the device isolation layer, a semiconductor pattern covering the central top surface and the inclined edge surface of the active region, the semiconductor pattern including a flat top surface of a (100) crystal plane that is parallel with the central top surface of the active region and a sidewall that is substantially perpendicular to the flat top surface, and a gate pattern overlapping the semiconductor pattern.

Abstract: A semiconductor structure, such as a CMOS semiconductor structure, includes a field effect device that includes a plurality of source and drain regions that are asymmetric. Such a source region and drain region asymmetry is induced by fabricating the semiconductor structure using a semiconductor substrate that includes a horizontal plateau region contiguous with and adjoining a sloped incline region. Within the context of a CMOS semiconductor structure, such a semiconductor substrate allows for fabrication of a pFET and an nFET upon different crystallographic orientation semiconductor regions, while one of the pFET and the nFET (i.e., typically the pFET) has asymmetric source and drain regions.

Abstract: Memory cell structures, including PSOIs, NANDs, NORs, FinFETs, etc., and methods of fabrication have been described that include a method of epitaxial silicon growth. The method includes providing a silicon layer on a substrate. A dielectric layer is provided on the silicon layer. A trench is formed in the dielectric layer to expose the silicon layer, the trench having trench walls in the <100> direction. The method includes epitaxially growing silicon between trench walls formed in the dielectric layer.

Abstract: A method for manufacturing a field effect transistor, includes: forming a mask of an insulating film on a semiconductor layer containing Si formed on a semiconductor substrate; forming the semiconductor layer into a mesa structure by performing etching with the use of the mask, the mesa structure extending in a direction parallel to an upper face of the semiconductor substrate; narrowing a distance between two sidewalls of the mesa structure and flattening the sidewalls by performing a heat treatment in a hydrogen atmosphere, the two sidewalls extending in the direction and facing each other; forming a gate insulating film covering the mesa structure having the sidewalls flattened; forming a gate electrode covering the gate insulating film; and forming source and drain regions at portions of the mesa structure, the portions being located on two sides of the gate electrode.

Abstract: A semiconductor device comprises a fin and a metal gate film. The fin is formed on a surface of a semiconductor material. The metal gate film formed on the fin and comprises ions implanted in the metal gate film to form a compressive stress within the metal gate. In one exemplary embodiment, the surface of the semiconductor material comprises a (100) crystalline lattice orientation, and an orientation of the fin is along a <100> direction with respect to the crystalline lattice of the semiconductor. In another exemplary embodiment, the surface of the semiconductor material comprises a (100) crystalline lattice orientation, and the orientation of the fin is along a <110> direction with respect to the crystalline lattice of the semiconductor. The fin comprises an out-of-plane compression that is generated by the compressive stress within the metal gate film.

Abstract: A semiconductor device includes an insulator layer, and an n-channel MIS transistor having an n channel and a pMIS transistor having a p channel which are formed on the insulator layer, wherein the n channel of the n-channel MIS transistor is formed of an Si layer having a uniaxial tensile strain in a channel length direction, the p channel of the p-channel MIS transistor is formed of an SiGe or Ge layer having a uniaxial compressive strain in the channel length direction, and the channel length direction of each of the n-channel MIS transistor and the p-channel MIS transistor is a <110> direction.

Abstract: An active region and an isolation region are formed in the surface of a silicon semiconductor substrate having a (100) crystal plane as a principal surface. A gate insulating film and a gate electrode are formed on the active region in this order. A stress control film is formed to cover part of the active region where the gate electrode is not formed, the isolation region, the top surface of the gate electrode and sidewalls. A pair of stress control regions are formed to sandwich the gate electrode in the gate width direction of the gate electrode. In the stress control regions, the stress control film is not formed, or alternatively, a stress control film thinner than the stress control film formed on the gate electrode is formed.

Abstract: A three-dimensional CMOS circuit having at least a first N-conductivity field-effect transistor and a second P-conductivity field-effect transistor respectively formed on first and second crystalline substrates. The first field-effect transistor is oriented, in the first substrate, with a first secondary crystallographic orientation. The second field-effect transistor is oriented, in the second substrate, with a second secondary crystallographic orientation. The orientations of the first and second transistors form a different angle from the angle formed, in one of the substrates, by the first and second secondary crystallographic directions. The first and second substrates are assembled vertically.

Abstract: Provided are a transferred thin film transistor and a method of manufacturing the same. The method includes: forming a source region and a drain region that extend in a first direction in a first substrate and a channel region between the source region and the drain region; forming trenches that extend in a second direction in the first substrate to define an active layer between the trenches, the second direction intersecting the first direction; separating the active layer between the trenches from the first substrate by performing an anisotropic etching process on the first substrate inside the trenches; attaching the active layer on a second substrate; and forming a gate electrode in the first direction on the channel region of the active layer.