Abstract: A semiconductor device includes a substrate of a first type of conductivity provided with at least one gate on one of its faces, and at least two doped regions of a second type of conductivity for forming a drain region and a source region. The two doped regions are arranged in the substrate flush with the face of the substrate on each side of a region of the substrate located under the gate for forming a channel between the drain and source regions. At least one region of doping agents of the second type of conductivity is implanted only in the channel.

Abstract: This disclosure describes an improved process and resulting structure that allows a single masking step to be used to define both the body and the threshold adjustment layer of the body. The method consists of forming a first mask on a surface of a substrate with an opening exposing a first region of the substrate; implanting through the opening a first impurity of a first conductivity type and having a first diffusion coefficient; and implanting through the opening a second impurity of the first conductivity type and having a second diffusion coefficient lower than the first diffusion coefficient. The first and second impurities are then co-diffused to form a body region of a field effect transistor. The remainder of the device is formed.

Abstract: One aspect of the inventors' concept relates to a method of forming a semiconductor device. In this method, a gate structure is formed over a semiconductor body. A source/drain mask is patterned over the semiconductor body implanted source and drain regions are formed that are associated with the gate structure. After forming the implanted source and drain regions, a multi-stage implant is performed on the source and drain regions that comprises at least two implants where the dose and energy of the first implant varies from the dose and energy of the second implant. Other methods and devices are also disclosed.

Abstract: A method of fabricating a semiconductor device may include forming a well in a semiconductor substrate, and then forming a gate oxide on and/or over the semiconductor substrate, and then forming a gate on and/or over the gate oxide, and then forming a pocket under the gate, and then performing a first spike anneal on the semiconductor substrate, and then performing a deep source/drain implant process on the semiconductor substrate, and then performing a second spike anneal on the semiconductor substrate.

Abstract: To provide a semiconductor device having lower junction capacitance, which can be manufactured with lower power consumption through a simpler process as compared with conventional, a semiconductor device includes a base substrate; a semiconductor film formed over the base substrate; a gate insulating film formed over the semiconductor film; and an electrode formed over the gate insulating film. The semiconductor film has a channel formation region which overlaps with the electrode with the gate insulating film interposed therebetween, a cavity is formed between a recess included in the semiconductor film and the base substrate, and the channel formation region is in contact with the cavity on the recess.

Abstract: An insulated-gate field-effect transistor (100, 100V, 140, 150, 150V, 160, 170, 170V, 180, 180V, 190, 210, 210W, 220, 220U, 220V, 220W, 380, or 480) is fabricated so as to have a hypoabrupt vertical dopant profile below one (104 or 264) of its source/drain zones for reducing the parasitic capacitance along the pn junction between that source/drain zone and adjoining body material (108 or 268). In particular, the concentration of semiconductor dopant which defines the conductivity type of the body material increases by at least a factor of 10 in moving from that source/drain zone down to an underlying body-material location no more than 10 times deeper below the upper semiconductor surface than that source/drain zone. The body material is preferably provided with a more heavily doped pocket portion (120 or 280) situated along the other source/drain zone (102 or 262).

Abstract: A method for forming an NMOS transistor for use in a flash memory cell on a P-type semiconductor structure includes forming a photoresist layer over the semiconductor structure and patterning the photoresist layer using a source/drain mask for the NMOS transistor; forming a first N-type region and a second N-type region by a first implantation process using the patterned photoresist as an implant mask where the first implantation process uses a high implant dose at a low implant energy and the first and second N-type regions form the source and drain regions of the NMOS transistor; forming a channel doped region by a second implantation process using the patterned photoresist as an implant mask where the second implantation process uses a low implant dose at a high implant energy and the channel doped region is formed for adjusting a threshold voltage of the NMOS transistor.

Abstract: A transistor includes a channel region with a first portion and a second portion. A length of the first portion is smaller than a length of the second portion. The first portion has a higher threshold voltage than the second portion. The lower threshold voltage of the second portion allows for an increased ON current. Despite the increase attained in the ON current, the higher threshold voltage of the first portion maintains or lowers a relatively low OFF current for the transistor.

Abstract: A gated microelectronic device is provided that has a source with a source ohmic contact with the source characterized by a source dopant type and concentration. A drain with a drain ohmic contact with the drain characterized by a drain dopant type and concentration. An intermediate channel portion characterized by a channel portion dopant type and concentration. An insulative dielectric is in contact with the channel portion and overlaid in turn by a gate. A gate contact applies a gate voltage bias to control charge carrier accumulation and depletion in the underlying channel portion. This channel portion has a dimension normal to the gate which is fully depleted in the off-state. The dopant type is the same across the source, drain and the channel portion of the device. The device on-state current is determined by the doping and, unlike a MOSFET, is not directly proportional to device capacitance.

Abstract: A method for making a semiconductor device includes providing a first substrate region and a second substrate region, wherein at least a part of the first substrate region has a first conductivity type and at least a part of the second substrate region has a second conductivity type different from the first conductivity type. The method further includes forming a dielectric layer over at least a portion of the first substrate region and at least a portion of the second substrate region. The method further includes forming a metal-containing gate layer over at least a portion of the dielectric layer overlying the first substrate region. The method further includes introducing dopants into at least a portion of the first substrate region through the metal-containing gate layer.

Abstract: A threshold voltage adjusted long-channel transistor fabricated according to short-channel transistor processes is described. The threshold-adjusted transistor includes a substrate with spaced-apart source and drain regions formed in the substrate and a channel region defined between the source and drain regions. A layer of gate oxide is formed over at least a part of the channel region with a gate formed over the gate oxide. The gate further includes at least one implant aperture formed therein with the channel region of the substrate further including an implanted region within the channel between the source and drain regions. Methods for forming the threshold voltage adjusted transistor are also disclosed.

Abstract: A memory capable of reducing the memory cell size is provided. This memory includes a first conductive type first impurity region formed on a memory cell array region of the main surface of a semiconductor substrate for functioning as a first electrode of a diode included in a memory cell and a plurality of second conductive type second impurity regions, formed on the surface of the first impurity region at a prescribed interval, each functioning as a second electrode of the diode.

Abstract: A transistor having an electrode layer that can reduce or prevent a coupling effect, a fabricating method thereof, and an image sensor having the same are provided. The transistor includes a semiconductor substrate and a well of a first conductivity type formed on the semiconductor substrate. A heavily-doped first impurity region of a first conductivity type surrounds an active region defined in the well. Heavily-doped second and third impurity regions of a second conductivity type are spaced apart from each other in the active region an define a channel region interposed therebetween. A gate is formed over the channel region to cross the active region. The gate overlaps at least a portion of the first impurity region and receives a first voltage. An electrode layer is formed between the semiconductor substrate and the gate, such that the electrode layer overlaps a portion of the first impurity region contacting the channel region and receives a second voltage.

Abstract: A semiconductor structure includes a stepped source and drain region located in part within a semiconductor substrate that preferably has a step in a direction of a gate electrode located over a channel region that adjoins the stepped source and drain region within the semiconductor substrate. A stepped portion of the stepped source and drain region covers an extension region within the stepped source and drain region.

Abstract: The present invention provides a method for manufacturing a semiconductor device, by which a transistor including an active layer, a gate insulating film in contact with the active layer, and a gate electrode overlapping the active layer with the gate insulating film therebetween is provided; an impurity is added to a part of a first region overlapped with the gate electrode with the gate insulating film therebetween in the active layer and a second region but the first region in the active layer by adding the impurity to the active layer from one oblique direction; and the second region is situated in the one direction relative to the first region.

Abstract: A low noise transistor and a method of making a low noise transistor. A noise-reducing agent is introduced into the gate electrode and then moved into the gate dielectric of a transistor.

Abstract: A device comprising a doped semiconductor nano-component and a method of forming the device are disclosed. The nano-component is one of a nanotube, nanowire or a nanocrystal film, which may be doped by exposure to an organic amine-containing dopant. Illustrative examples are given for field effect transistors with channels comprising a lead selenide nanowire or nanocrystal film and methods of forming these devices.

Abstract: A improved MOSFET (50, 51, 75, 215) has a source (60) and drain (62) in a semiconductor body (56), surmounted by an insulated control gate (66) located over the body (56) between the source (60) and drain (62) and adapted to control a conductive channel (55) extending between the source (60) and drain (62). The insulated gate (66) is perforated by a series of openings (61) through which highly doped regions (69) in the form of a series of (e.g., square) dots (69) of the same conductivity type as the body (56) are provided, located in the channel (55), spaced apart from each other and from the source (60) and drain (62). These channel dots (69) are desirably electrically coupled to a highly doped contact (64) to the body (56). The resulting device (50, 51, 75, 215) has a greater SOA, higher breakdown voltage and higher HBM stress resistance than equivalent prior art devices (20) without the dotted channel. Threshold voltage is not affected.

Abstract: A semiconductor device which, in spite of the existence of a dummy active region, eliminates the need for a larger chip area and improves the surface flatness of the semiconductor substrate. In the process of manufacturing it, a thick gate insulating film for a high voltage MISFET is formed over an n-type buried layer as an active region and a resistance element IR of an internal circuit is formed over the gate insulating film. Since the thick gate insulating film lies between the n-type buried layer and the resistance element IR, the coupling capacitance produced between the substrate (n-type buried layer) and the resistance element IR is reduced.

Abstract: A transistor includes: a semiconductor substrate; a channel region arranged on the semiconductor substrate; a source and a drain respectively arranged on either side of the channel region; and a conductive nano tube gate arranged on the semiconductor substrate to transverse the channel region between the source and the drain. Its method of manufacture includes: arranging a conductive nano tube on a surface of a semiconductor substrate; defining source and drain regions having predetermined sizes and traversing the nano tube; forming a metal layer on the source and drain regions; removing a portion of the metal layer formed on the nano tube to respectively form source and drain electrodes separated from the metal layer on either side of the nano tube; and doping a channel region below the nano tube arranged between the source and drain electrodes by ion-implanting.

Abstract: Transistors having a high carrier mobility and devices incorporating the same are fabricated by forming a preliminary semiconductor layer in a semiconductor substrate at both sides of a gate pattern. A source/ drain semiconductor layer having a heterojunction with the semiconductor substrate is formed by irradiating a laser beam onto the preliminary semiconductor layer. The source/drain semiconductor layer is formed in a recrystallized single crystal structure.

Abstract: There are disclosed TFTs that have excellent characteristics and can be fabricated with a high yield. The TFTs are fabricated, using an active layer crystallized by making use of nickel. Gate electrodes are comprising tantalum. Phosphorus is introduced into source/drain regions. Then, a heat treatment is performed to getter nickel element in the active layer and to drive it into the source/drain regions. At the same time, the source/drain regions can be annealed out. The rate electrodes of tantalum can withstand this heat treatment.

Abstract: A semiconductor device and fabricating method thereof in which a lightly doped drain junction is graded using a diffusion property of dopant implanted in heavily doped source/drain region are disclosed. An example semiconductor device includes a gate electrode having a gate insulating layer underneath and disposed on a semiconductor substrate; a pair of lightly doped regions separated from each other in the semiconductor substrate and aligned with the gate electrode; a pair of heavily doped regions separated from each other in the semiconductor substrate and partially overlapped with the pair of the lightly doped regions, respectively; and a pair of diffusion source/drain regions enclosing the pair of the lightly doped regions therein.

Abstract: A method for manufacturing a nonvolatile semiconductor memory device having a step of forming a first gate electrode on a peripheral circuit portion and a second gate electrode on a memory cell portion, a step of introducing impurity into the peripheral circuit portion and memory cell portion, a step of forming a first insulating film above at least the memory cell portion, and a step of annealing the semiconductor substrate into which the impurity has been introduced. The first gate electrode has a first gate length. The second gate electrode has a second gate length shorter than the first gate length.

Abstract: Methods fabricate DEMOS devices having varied channel lengths and substantially similar threshold voltages. A threshold voltage is selected for first and second devices. First and second well regions are formed. First and second drain extension regions are formed within the well regions. First and second back gate regions are formed within the well regions according to the selected threshold voltage. First and second gate structures are formed over the first and second well regions having varied channel lengths. A first source region is formed in the first back gate region and a first drain region is formed in the first drain extension region. A second source region is formed in the second back gate region and a second drain region is formed in the drain extension region.

Abstract: A semiconductor device including a metal oxide layer, a channel area of the metal oxide layer, a preservation layer formed on the channel area of the metal oxide layer, and at least two channel contacts coupled to the channel area of the metal oxide layer, and a method of forming the same.

Abstract: A method of forming an abrupt junction device with a semiconductor substrate is provided. A gate dielectric is formed on a semiconductor substrate, and a gate is formed on the gate dielectric. A sidewall spacer is formed on the semiconductor substrate adjacent the gate and the gate dielectric. A thickening layer is formed by selective epitaxial growth on the semiconductor substrate adjacent the sidewall spacer. Raised source/drain dopant implanted regions are formed in at least a portion of the thickening layer. Silicide layers are formed in at least a portion of the raised source/drain dopant implanted regions to form source/drain regions, beneath the silicide layers, that are enriched with dopant from the silicide layers. A dielectric layer is deposited over the silicide layers, and contacts are then formed in the dielectric layer to the silicide layers.

Abstract: A semiconductor device including at least one of: lightly doped drain regions over a semiconductor substrate; a gate insulating layer over a semiconductor substrate between lightly doped drain regions; and/or a gate formed at an upper side of a gate insulating layer. A lower width of a gate may be less than an interval between lightly doped drain regions. An upper width of a gate may be greater than an interval between lightly doped drain regions.

Abstract: In a channel region between the source/drain diffusion layers, impurities of the same conductivity type as the well are doped in an area apart from the diffusion regions. By using as a mask the gate formed in advance, tilted ion implantation in opposite directions is performed to form the diffusion layers and heavily impurity doped region of the same conductivity type as the well in a self-alignment manner relative to the gate.

Abstract: To increase the density of memory cells, a multibit memory cell (10, 50, 80, 110) can be manufactured by preventing the formation of at least one of the extension regions usually formed for the source or drain region. In one embodiment, a single mask (24) blocks the doping of the extension regions during ion implantation. If a tilt implantation process is used to form desired extension regions, two masks may be used. The process can also be integrated into a disposable spacer process. By blocking the extension region for a current electrode, a programmable region (32, 76, 102, 132) is formed adjacent a current electrode. The programmable region enables a two-bit memory cell to be formed.

Abstract: A method of forming a channel region for a MOSFET device in a strained silicon layer via employment of adjacent and surrounding silicon-germanium shapes, has been developed. The method features simultaneous formation of recesses in a top portion of a conductive gate structure and in portions of the semiconductor substrate not occupied by the gate structure or by dummy spacers located on the sides of the conductive gate structure. The selectively defined recesses will be used to subsequently accommodate silicon-germanium shapes, with the silicon-germanium shapes located in the recesses in the semiconductor substrate inducing the desired strained channel region. The recessing of the conductive gate structure and of semiconductor substrate portions reduces the risk of silicon-germanium bridging across the surface of sidewall spacers during epitaxial growth of the alloy layer, thus reducing the risk of gate to substrate leakage or shorts.

Abstract: A method for manufacturing a DRAM device includes a hydrogenating step conducted to source/drain diffused regions in a hydrogen ambient at a substrate temperature not lower than 350 degrees C., and a dehydrogenating step in an inactive gas ambient at a substrate temperature of lower than 350 degrees C., before a packaging step. If a defective cell having a lower refreshing time is found in the test before the packaging step, the defective cell is replaced by a redundant cell. The resultant DRAM has a lower degradation in the refreshing characteristic after the packaging step.

Abstract: A data writing method for mask read only memory using different doses of ion implantations to perform the data writing of Mask Read Only Memory. A semiconductor substrate having a plurality of gate structures is provided. The different ion implantations are performed depending on the mask from the user, thereby generating the different voltage output values. The different voltage output values are set as (00), (01), (10), and (11) for the bit output. Therefore, the present invention reduces the area of memory required for a specific data record, and lowers the production cost.

Abstract: Semiconductor devices and methods of fabrication. A device includes a semiconductor substrate, a gate electrode insulated from the semiconductor substrate by a gate insulation layer, LDD-type source/drain regions formed at both sides of the gate electrode, an interlayer insulation layer formed over the gate electrode and the substrate, and a shared contact piercing the interlayer insulation layer and contacting the gate electrode and one of the LDD-type source/drain regions including at least a part of a lightly doped drain region. Multiple-layer spacers are formed on both sides of the gate structure and used as a mask in forming the LDD-type regions. At least one layer of the spacer is removed in the contact opening to widen the opening to receive a contact plug.

Abstract: A MOSFET with a short channel structure and manufacturing processes for the same are described. The MOSFET has a substrate, a channel region, a source/drain region, a gate dielectric layer and a conductive layer. The channel region in the substrate includes a first region and a second region, in which the first region has a first threshold voltage and the second region has a second threshold voltage, respectively. The first threshold voltage is smaller than the second threshold voltage. The first threshold voltage of the first region can also be adjusted to reduce or increase effectively the resistance of the MOSFET when the MOSFET is turned on or off. Additionally, the first region has a shallower junction depth than that of the normal source/drain extension.

Abstract: A method for fabricating double-gate and tri-gate transistors in the same process flow is described. In one embodiment, a sacrificial layer is formed over stacks that include semiconductor bodies and insulative members. The sacrificial layer is planarized prior to forming gate-defining members. After forming the gate-defining members, remaining insulative member portions are removed from above the semiconductor body of the tri-gate device but not the I-gate device. This facilitates the formation of metallization on three sides of the tri-gate device, and the formation of independent gates for the I-gate device.

Abstract: A semiconductor device (10) is formed by positioning a gate (22) overlying a semiconductor layer (16) of preferably silicon. A semiconductor material (26) of, for example only, SiGe or Ge, is formed adjacent the gate over the semiconductor layer and over source/drain regions. A thermal process diffuses the stressor material into the semiconductor layer. Lateral diffusion occurs to cause the formation of a strained channel (17) in which a stressor material layer (30) is immediately adjacent the strained channel. Extension implants create source and drain implants from a first portion of the stressor material layer. A second portion of the stressor material layer remains in the channel between the strained channel and the source and drain implants. A heterojunction is therefore formed in the strained channel. In another form, oxidation of the stressor material occurs rather than extension implants to form the strained channel.

Abstract: The present invention provides, in one embodiment, a method of reducing 1/f noise in a metal oxide semiconductor (MOS) device (100). The method comprises forming an oxide layer (110) on a silicon substrate (105) and depositing a polysilicon layer (115) on the oxide layer (110). The method further includes implanting a fluorine dopant (130) into the polysilicon layer (115) at an implant dose of at least about 4×1014 atoms/cm2. The polysilicon layer (115) is thermally annealed such that a portion of the fluorine dopant (130) is diffused into the oxide layer (110) to thereby reduce a 1/f noise of the MOS device (100). Other embodiments of the provide a MOS device (300) manufactured by the above-described method and a method of manufacturing an integrated circuit (500) that includes the above-described method.

Abstract: The present invention discloses a mask ROM which has excellent compatibility with a logic process and improves integration of a memory cell, and a fabrication method thereof. The mask ROM includes: a substrate where a memory cell array region and a segment select region are defined; first and second trenches respectively formed at the outer portion of the memory cell array region and at the outer portion of a buried layer formation region of the segment select region; an element isolating film and an isolating pattern respectively filling up the first and second trenches; a plurality of buried layers aligned on the substrate in a first direction by a predetermined interval, and surrounded by the isolating pattern; and a plurality of gates aligned in a second direction to cross the buried layers in an orthogonal direction.

Abstract: A method of formation of a deep trench vertical transistor is provided. A deep trench with a sidewall in a doped semiconductor substrate is formed. The semiconductor substrate includes a counterdoped drain region in the surface thereof and a channel alongside the sidewall. The drain region has a top level and a bottom level. A counterdoped source region is formed in the substrate juxtaposed with the sidewall below the channel. A gate oxide layer is formed on the sidewalls of the trench juxtaposed with a gate conductor. Perform the step of recessing the gate conductor below the bottom level of the drain region followed by performing angled ion implantation at an angle ?+? with respect to vertical of a counterdopant into the channel below the source region and performing angled ion implantation at an angle ? with respect to vertical of a dopant into the channel below the source.

Abstract: A method of forming a retrograde well in a transistor is provided. A transistor structure having a substrate, a gate, and a gate oxide layer between the substrate and the gate is formed. The substrate includes a channel region located generally below the gate. A first dopant is implanted into the channel region. A second dopant is implanted into the substrate to form a doped source region and a doped drain region. A third dopant is implanted into the gate oxide layer. A source/drain anneal is performed to form a source and a drain in the doped source region and the doped drain region, respectively. The source/drain anneal causes a portion of the first dopant in the channel region to be attracted by the third dopant into the gate oxide layer.

Abstract: Various methods of fabricating halo regions are disclosed. In one aspect, a method of manufacturing is provided that includes forming a symmetric transistor and an asymmetric transistor on a substrate. A first mask is formed on the substrate with a first opening to enable implantation formation of first and second halo regions proximate first and second source/drain regions of the symmetric transistor. First and second halo regions of a first dosage are formed beneath the first gate by implanting off-axis through the first opening. A second mask is formed on the substrate with a second opening to enable implantation formation of a third halo region proximate a source region of the second asymmetric transistor while preventing formation of a halo region proximate a drain region of the asymmetric transistor. A third halo region of a second dosage greater than the first dosage is formed by implanting off-axis through the second opening.

Abstract: To provide a cavity in the portion of the silicon substrate which lies beneath the channel region of the MOS transistor.

Abstract: In a nonvolatile memory cell, the floating gate (160) has an upward protruding portion. This portion can be formed as a spacer over a sidewall of the select gate (140). The spacer can be formed from a layer (160.2) deposited after the layer (160.1) which provides a lower portion of the floating gate. Alternatively, the upward protruding portion and the lower portion can be formed from the same layers or sub-layers all of which are present in both portions. The control gate (170) can be defined without photolithography. Other embodiments are also provided.

Abstract: A MOS transistor includes a drain zone, a source zone, and a gate electrode. Doping atoms of the first conductivity type are implanted in the region of the drain zone and the source zone by at least two further implantation steps such that a pn junction between the drain zone and a substrate region is vertically shifted and a voltage ratio of the MOS transistor between a lateral breakdown voltage and a vertical breakdown voltage can be set.

Abstract: A semiconductor integrated circuit which is capable of being manufactured with a higher packing density and a small-size structure of standard cells is described. In the semiconductor integrated circuit, substrate regions and source regions are shared by adjacent standard cells as well as common contact regions which are located inward displaced respectively from the centers of the substrate regions.

Abstract: An asymmetrical channel implant from source to drain improves short channel characteristics. The implant provides a relatively high VT net dopant adjacent to the source region and a relatively low VT net dopant in the remainder of the channel region. One way to achieve this arrangement with disposable gate processing is to add disposable sidewalls inside the gate opening (after removing the disposable gate), patterning to selectively remove the source or gate side sidewalls, implant the source and drain regions and remove the remaining sidewall and the proceed. According to a second embodiment, wherein the channel implant can be symmetrical, a relatively low net VT implant is provided in the central region of the channel and a relatively high net VT implant is provided in the channel regions adjacent to the source and drain regions.

Abstract: CMOS devices formed with a Silicon On Insulator (SOI) technology with reduced Drain Induced Barrier Lowering (DIBL) characteristics and a method for producing the same. The method involves a high energy, high dose implant through openings in a masking layer and through channel regions of the p- and n-wells, into the insulator layer, thereby creating a borophosphosilicate glass (BPSG) diffusion source within the insulation layer underlying the gate regions of the SOI wafer substantially between the source and drain. Backend high temperature processing steps induce diffusion of the dopants contained in the diffusion source into the p- and n-wells, thereby forming asymmetric retrograde dopant profiles in the channel under the gate. The method can be selectively applied to selected portions of a wafer to tailor device characteristics, such as for memory cells.

Abstract: Method to form a structure to decrease area capacitance within a buried insulator device structure is disclosed. A portion of the substrate layer of a buried insulator structure opposite the insulator layer from the gate is doped with the same doping polarity as the source and drain regions of the device, to provide reduced area capacitance. Such doping may be limited to portions of the substrate which are not below the gate.

Abstract: A method for testing semiconductor chips, in particular semiconductor memory chips, is described. In which, in a chip to be tested, at least one test mode is set, the test mode is executed in the chip and test results are output from the chip. It is provided that, after the setting and before the performance of the test mode, a check mode is executed in which the status of the test mode set in the chip is read out in a defined format.