Abstract: A method for fabricating a semiconductor device includes forming a plurality of bodies that are each isolated from another by a trench and each include a diffusion barrier region with a sidewall exposed to the trench, forming a doped layer gap-filling the trench, forming a sidewall junction at the exposed sidewall of the diffusion barrier region by annealing the doped layer, and forming a conductive line coupled with the sidewall junction to fill the trench.

Abstract: A semiconductor device is formed on a semiconductor substrate. The device comprises a drain; an epitaxial layer overlaying the drain; a body disposed in the epitaxial layer, having a body top surface and a body bottom surface; a source embedded in the body, extending from the body top surface into the body; a first gate trench extending into the epitaxial layer; a first gate disposed in the first gate trench; an active region contact trench extending through the source and at least part of the body into the drain; an active region contact electrode disposed within the active region contact trench; a second gate trench extending into the epitaxial layer; a second gate disposed in the gate trench; a gate contact trench formed within the second gate; and a gate contact electrode disposed within the gate contact trench.

Abstract: A monolithically integrated trench FET and Schottky diode includes a plurality of trenches extending into a FET region and a Schottky region of a semiconductor layer. A trench in the Schottky region includes a dielectric layer lining the trench sidewalls, and a conductive electrode having a top surface that is substantially coplanar with a top surface of the semiconductor layer adjacent the trench. An interconnect layer electrically contacts the top surface of the semiconductor layer adjacent the trench so as to form a Schottky contact with the top surface of the semiconductor layer adjacent the trench. A surface of the semiconductor layer in the Schottky region is lower relative to a surface of the semiconductor layer in the FET region.

Abstract: A semiconductor device including a vertical transistor and a method for manufacturing the same may reduce a cell area in comparison with a conventional layout of 8F2 and 6F2. Also, the method does not require forming a bit line contact, a storage node contact or a landing plug, thereby decreasing the process steps.

Abstract: A vertical super junction MOSFET and a lateral MOSFET are integrated on the same semiconductor substrate. The lateral MOSFET is electrically isolated from the vertical super junction MOSFET by an n-buried isolating layer and an n-diffused isolating layer. The lateral MOSFET is formed of a p-well region formed in an n? semiconductor layer bounded by the n-buried isolating layer and n-diffused isolating layer, an n-source region and n-drain region formed in the p-well region, and a gate electrode that covers a portion of the p-well region sandwiched by the n-source region and n-drain region. As the n-buried isolating layer is formed at the same time as an n-layer (3) of the vertical super junction MOSFET, it is possible to reduce cost. Also, it is possible to suppress parasitic action between the elements with the n-buried isolating layer.

Abstract: A dual channel trench LDMOS transistor includes a semiconductor layer of a first conductivity type formed on a substrate; a first trench formed in the semiconductor layer where a trench gate is formed in an upper portion of the first trench; a body region of the second conductivity type formed in the semiconductor layer adjacent the first trench; a source region of the first conductivity type formed in the body region and adjacent the first trench; a planar gate overlying the body region; a drain drift region of the first conductivity type formed in the semiconductor layer and in electrical contact with a drain electrode. The planar gate forms a lateral channel in the body region, and the trench gate in the first trench forms a vertical channel in the body region of the LDMOS transistor.

Abstract: A semiconductor device contains a first transistor including a single trench which is formed on a substrate between a source region and a drain region and a gate electrode which is formed in the single trench, a second transistor including at least two trenches which are formed on the substrate between a source region and a drain region and a gate electrode which is formed in the at least two trenches, and also contains a device isolation insulating which isolates the region in which the transistor is formed. The first transistor has first distance between the single trench and the device isolation insulating film and the second transistor has second distance between the adjoining trenches, such the first distance is less than the second distance in a gate width direction.

Abstract: A method for fabricating a semiconductor device includes forming a plurality of trenches using a first mask. The trenches include source pickup trenches located in outside a termination area and between two adjacent active areas. First and second conductive regions separated by an intermediate dielectric region are formed using a second mask. A first electrical contact to the first conductive region and a second electrical contact to the second conductive region are formed using a third mask and forming a source metal region. Contacts to a gate metal region are formed using a fourth mask. A semiconductor device includes a source pickup contact located outside a termination region and outside an active region of the device.

Abstract: In one general aspect, an apparatus can include a plurality of trench metal-oxide-semiconductor field effect transistors (MOSFET) devices formed within an epitaxial layer of a substrate, and a gate-runner trench disposed around the plurality of trench MOSFET devices and disposed within the epitaxial layer. The apparatus can also include a floating-field implant defined by a well implant and disposed around the gate-runner trench.

Abstract: An integrated circuit comprising trench MOSFET having trenched source-body contacts and trench Schottky rectifier having trenched anode contacts is disclosed. By employing the trenched contacts in trench MOSFET and trench Schottky rectifier, the integrated circuit is able to be shrunk to achieve low specific on-resistance for trench MOSFET, and low Vf and reverse leakage current for trench Schottky Rectifier.

Abstract: The present invention provides a semiconductor device including a semiconductor substrate having a first conductive type, at least one high-side transistor device and at least one low-side transistor device. The high-side transistor device includes a doped high-side base region having a second conductive type, a doped high-side source region having the first conductive type and a doped drain region having the first conductive type. The doped high-side base region is disposed within the semiconductor substrate, and the doped high-side source region and the doped drain region are disposed within the doped high-side base region. The doped high-side source region is electrically connected to the semiconductor substrate, and the semiconductor substrate is regarded as a drain of the low-side transistor device.

Abstract: A semiconductor device according to the present invention includes: a semiconductor layer of a first conductivity type; a body region of a second conductivity type formed in a surface layer portion of the semiconductor layer; a trench dug from the surface of the semiconductor layer to penetrate the body region; a source region of a first conductivity type formed on a side portion of the trench in a surface layer portion of the body region; a gate insulating film formed on the bottom surface and the side surface of the trench; a gate electrode embedded in the trench through the gate insulating film and so formed that the surface thereof is lower by one stage than the surface of the source region; and a peripheral wall film formed on a peripheral edge portion of the surface of the gate electrode to be opposed to an upper end portion of the side surface of the trench.

Abstract: A semiconductor memory device has an asymmetric buried gate structure with a stepped top surface and a method for fabricating the same. The method for fabricating the semiconductor memory device includes: etching a predetermined region of a semiconductor substrate to form an isolation layer defining an active region; forming a recess within the active region; forming a metal layer filling the recess; asymmetrically etching the metal layer to form an asymmetric gate having a stepped top surface at a predetermined portion of the recess; and forming a capping oxide layer filling a remaining portion of the recess where the asymmetric gate is not formed, thereby obtaining an asymmetric buried gate including the asymmetric gate and the capping oxide layer.

Abstract: A semiconductor component that includes an edge termination structure and a method of manufacturing the semiconductor component. A semiconductor material has a semiconductor device region and an edge termination region. One or more device trenches may be formed in the semiconductor device region and one or more termination trenches is formed in the edge termination region. A source electrode is formed in a portion of a termination trench adjacent its floor and a floating electrode termination structure is formed in the portion of the termination trench adjacent its mouth. A second termination trench may be formed in the edge termination region and a non-floating electrode may be formed in the second termination trench. Alternatively, the second termination trench may be omitted and a trench-less non-floating electrode may be formed in the edge termination region.

Abstract: According to an embodiment, a semiconductor device includes a first trench being provided in an N+ substrate. An N layer, an N? layer, a P layer, and an N+ layer are formed in a stacked manner to cover the first trench. The semiconductor device includes second and third trenches. The P+ layer is formed to cover the second trench. The trench gates are formed to cover the third trenches.

Abstract: A semiconductor device includes a semiconductor body having a first surface and a second surface, at least one electrode arranged in at least one trench extending from the first surface into the semiconductor body, and a semiconductor via extending in a vertical direction of the semiconductor body within the semiconductor body to the second surface. The semiconductor via is electrically insulated from the semiconductor body by a via insulation layer. The at least one electrode extends in a first lateral direction of the semiconductor body through the via insulation layer and is electrically connected to the semiconductor via.

Abstract: A multi-phase voltage regulator is disclosed where each phase is comprised of an array of high and low side transistors that are integrated onto a single substrate. Further, a system of mounting the voltage regulator onto a flip chip and lead frame is disclosed wherein the source and drain lines form an interdigital pattern.

Abstract: A semiconductor device has a source region, channel region, and drain region disposed in order from the surface of the device in the thickness direction of a semiconductor substrate. The device includes a source metal embedded in a source contact groove penetrating the source region and reaching the channel region, a gate insulating film formed on the side wall of a gate trench that is formed to penetrate the source region and channel and reach the drain region, a polysilicon gate embedded in trench so that at least a region facing the channel region in the insulating film is covered with the gate and so that the entire gate is placed under a surface of the source region, and a gate metal that is embedded in a gate contact groove formed in the gate so as to reach the depth of the channel region and in contact with the gate.

Abstract: There is disclosed a substrate processing apparatus including a processing chamber housing a substrate, pipes for supplying gas into the processing chamber, and heaters provided in the middle of the pipes, and heating the gas. In the substrate processing apparatus, the heaters heat the gas to a temperature lower than a temperature at which exhaust gas is generated from the pipes to dry the substrate in the heated gas.

Abstract: A single-sided access device includes an active fin structure comprising a source contact area and a drain contact area separated from each other by an isolation region therebetween; a trench isolation structure disposed at one side of the active fin structure, wherein the trench isolation structure intersects with the isolation region between the source contact area and the drain contact area; a sidewall gate disposed under the isolation region and on the other side of the active fin structure opposite to the trench isolation structure so that the active fin structure is sandwiched by the trench isolation structure and the sidewall gate, wherein the sidewall gate has multi-fingers that engage with the active fin structure; and a gate dielectric layer between the sidewall gate and the active fin structure.

Abstract: A semiconductor device and fabrication methods are disclosed. The device includes a plurality of gate electrodes formed in trenches located in an active region of a semiconductor substrate. A first gate runner is formed in the substrate and electrically connected to the gate electrodes, wherein the first gate runner surrounds the active region. A second gate runner is connected to the first gate runner and located between the active region and a termination region. A termination structure surrounds the first and second gate runners and the active region. The termination structure includes a conductive material in an insulator-lined trench in the substrate, wherein the termination structure is electrically shorted to a source or body layer of the substrate thereby forming a channel stop for the device.

Abstract: A device isolation layer is formed in a substrate to define spaced-apart linear active regions in the substrate. Buried gate patterns are formed in the substrate and extending along a first direction to cross the active regions. An etch stop layer and a first insulating layer are formed on the substrate. Bit line structures are formed on the first insulating layer and extending along a second direction transverse to the first direction to cross the active regions. A second insulating layer is formed on the bit line structures. Contact plugs are formed penetrating the second insulating layer, the first insulating layer, and the etch stop layer to contact one of the active regions between adjacent ones of the bit line structures.

Abstract: A vertical channel transistor array has an active region formed by a plurality of semiconductor pillars. A plurality of embedded bit lines are arranged in parallel in a semiconductor substrate and extended along a column direction. A plurality of bit line contacts are respectively disposed on a side of one of the embedded bit lines. A plurality of embedded word lines are arranged in parallel above the embedded bit lines and extended along a row direction. Besides, the embedded word lines connect the semiconductor pillars in the same row with a gate dielectric layer sandwiched between the embedded word lines and the semiconductor pillars. The current leakage isolation structure is disposed at terminals of the embedded bit lines to prevent current leakage between the adjacent bit line contacts.

Abstract: An embodiment of the invention provides a semiconductor fabrication method. The method comprises forming an isolation region between a first and a second region in a substrate, forming a recess in the substrate surface, and lining the recess with a uniform oxide. Embodiments further include doping a channel region under the bottom recess surface in the first and second regions and depositing a gate electrode material in the recess. Preferred embodiments include forming source/drain regions adjacent the channel region in the first and second regions, preferably after the step of depositing the gate electrode material. Another embodiment of the invention provides a semiconductor device comprising a recess in a surface of the first and second active regions and in the isolation region, and a dielectric layer having a uniform thickness lining the recess.

Abstract: A vertical transistor device includes a line of active area adjacent a line of dielectric isolation. A buried data/sense line obliquely angles relative to the line of active area and the line of dielectric isolation. A pair of gate lines is outward of the buried data/sense line and obliquely angle relative to the line of active area and the line of dielectric isolation. A vertical transistor channel region is within the active area between the pair of gate lines. An outer source/drain region is in the active area above the channel region and an inner source/drain region is in the active area below the channel region. The inner source/drain region is electrically coupled to the buried data/sense line. Other devices and structures are contemplated, as are methods of forming a plurality of vertical transistor devices.

Abstract: A metal gate structure comprises a metal layer partially filling a trench of the metal gate structure. The metal layer comprises a first metal sidewall, a second metal sidewall and a metal bottom layer. By employing an uneven protection layer during an etching back process, the thickness of the first metal sidewall is less than the thickness of the metal bottom layer and the thickness of the second metal sidewall is less than the thickness of the metal bottom layer. The thin sidewalls allow extra space for subsequent metal-fill processes.

Abstract: A semiconductor device of the present invention includes vertical double diffused MOS transistor. A gate electrode of the vertical double diffused MOS transistor is disposed within a trench formed on a semiconductor substrate and projects from a surface of the semiconductor substrate. On a side surface of the gate electrode, a side wall is formed. On the surface of the semiconductor substrate and a surface of the gate electrode, a metal silicide film is formed.

Abstract: A circuit structure including a semiconductor substrate having a depression; a first insulating layer positioned on the surface of the depression; a bottom conductor positioned in a bottom portion of the depression, wherein the bottom conductor is connected to an external bias through a plurality of longer vertical contact plugs; an upper conductor positioned in an upper portion of the depression, wherein the upper conductor is connected to a plurality of shorter vertical contact plugs, and a top surface of the upper conductor is higher than a depression-bearing surface of the semiconductor substrate; and a second insulating layer positioned between the bottom conductor and the upper conductor.

Abstract: A semiconductor device is disclosed having vertically stacked (also referred to as vertically offset) transistors in a semiconductor fin. The semiconductor fin may include lower transistors separated by a first trench and having a source and drain in a first doped region of the fin. The semiconductor fin also includes upper transistors vertically offset from the first transistors and separated by a second trench and having a source and drain in a second doped region of the fin. Upper and lower stacked gates may be disposed on the sidewalls of the fin, such that the lower transistors are activated by biasing the lower gates and upper transistors are activated by biasing the upper gates. Methods of manufacturing and operating the device are also disclosed.

Abstract: A data storing device may include a substrate, transistors on the substrate that include gate line structures, and conductive isolation patterns defining active regions of the transistors. Each conductive isolation pattern includes at least one portion buried in the substrate and the conductive isolation patterns are electrically connected with each other.

Abstract: In one embodiment, the invention comprises a MOSFET comprising individual MOSFET cells. Each cell comprises a U-shaped well (228) (P type) and two parallel sources (260) (N type) formed within the well. A plurality of source rungs (262) (doped N) connect sources (260) at multiple locations. Regions between two rungs (262) comprise a body (252) (P type). These features are formed on an N-type epitaxial layer (220), which is formed on an N-type substrate (216). A contact (290) extends across and contacts a plurality of source rungs (262) and bodies (252). Gate oxide and a gate contact overlie a leg of a first well and a leg of a second adjacent well, inverting the conductivity responsive to a gate voltage. A MOSFET comprises a plurality of these cells to attain a desired low channel resistance. The cell regions are formed using self-alignment techniques at several states of the fabrication process.

Abstract: A structure of power semiconductor device integrated with clamp diodes having separated gate metal pads is disclosed. The separated gate metal pads are wire bonded together on the gate lead frame. This improved structure can prevent the degradation of breakdown voltage due to electric field in termination region blocked by polysilicon or gate metal.

Abstract: A semiconductor device can be manufactured by a method that includes forming a structure that includes a plurality of layers of semiconductor material. One or more etching processes are performed on the multi-layered semiconductor structure, and then an Ar/O2 treatment is performed on the multi-layered semiconductor structure. The Ar/O2 treatment includes exposure of the structure to Ar ion bombardment and O2 molecular oxidation. The Ar/O2 treatment can be used to create a bottle-shaped structure.

Abstract: In one embodiment the present invention includes a semiconductor device. The semiconductor device comprises a first semiconductor region, a second semiconductor region and a trench region. The first semiconductor region is of a first conductivity type and a first conductivity concentration. The trench region includes a metal layer in contact with the first semiconductor region to form a metal-semiconductor junction. The second semiconductor region is adjacent to the first semiconductor region that has a second conductivity type and a second conductivity concentration. The second semiconductor region forms a PN junction with the first semiconductor region, and the trench region has a depth such that the metal-semiconductor junction is proximate to the PN junction.

Abstract: An oxide termination semiconductor device may comprise a plurality of gate trenches, a gate runner, and an insulator termination trench. The gate trenches are located in an active region. Each gate trench includes a conductive gate electrode. The insulator termination trench is located in a termination region that surrounds the active region. The insulator termination trench is filled with an insulator material to form an insulator termination for the semiconductor device. The device can be made using a three-mask or four-mask process.

Abstract: A semiconductor structure comprises trenches extending into a semiconductor region. Portions of the semiconductor region extend between adjacent trenches forming mesa regions. A gate electrode is in each trench. Well regions of a first conductivity type extend in the semiconductor region between adjacent trenches. Source regions of a second conductivity type are in the well regions. Heavy body regions of the first conductivity type are in the well regions. The source regions and the heavy body regions are adjacent trench sidewalls, and the heavy body regions extend over the source regions along the trench sidewalls to a top surface of the mesa regions.

Abstract: Methods of forming, devices, and apparatus associated with a vertical memory cell are provided. One example method of forming a vertical memory cell can include forming a semiconductor structure over a conductor line. The semiconductor structure can have a first region that includes a first junction between first and second doped materials. An etch-protective material is formed on a first pair of sidewalls of the semiconductor structure above the first region. A volume of the first region is reduced relative to a body region of the semiconductor structure in a first dimension.

Abstract: A method of fabricating a semiconductor device using a recess channel array is disclosed. A substrate is provided having a first region and a second region, including a first transistor in the first region including a first gate electrode partially filling a trench, and source and drain regions that are formed at both sides of the trench, and covered by a first insulating layer. A first conductive layer is formed on the substrate. A contact hole through which the drain region is exposed is formed by patterning the first conductive layer and the first insulating layer. A contact plug is formed that fills the contact hole. A bit line is formed that is electrically connected to the drain region through the contact plug, and simultaneously a second gate electrode is formed in the second region by patterning the first conductive layer.

Abstract: A method includes forming elongate structures on a first substrate, such that the material composition of each elongate structure varies along its length so as to define first and second physically different sections in the elongate structures. First and second physically different devices are then defined in the elongate structures. Alternatively, the first and second physically different sections may be defined in the elongate structures after they have been fabricated. The elongate structures may be encapsulated and transferred to a second substrate. The invention provides an improved method for the formation of a circuit structure that requires first and second physically different devices to be provided on a common substrate. In particular, only one transfer step is necessary.

Abstract: A semiconductor device having a saddle fin gate and a method for manufacturing the same are presented. The semiconductor device includes a semiconductor substrate, an isolation structure, and gates. The semiconductor substrate is defined with first grooves in gate forming areas. The isolation structure is formed in the semiconductor substrate and is defined with second grooves which expose front and rear surfaces of the gate forming areas. The gates are formed within the first grooves in the gate forming areas. Gates are also formed in the second grooves of the isolation structure to cover the exposed front and rear surfaces of the gate forming areas. The second grooves are wider at the lower portions that at the upper portions.

Abstract: This invention discloses a semiconductor power device disposed in a semiconductor substrate comprising a lightly doped layer formed on a heavily doped layer and having an active cell area and an edge termination area. The edge termination area comprises a plurality P-channel MOSFETs. By connecting the gate to the drain electrode, the P-channel MOSFET transistors formed on the edge termination are sequentially turned on when the applied voltage is equal to or greater than the threshold voltage Vt of the P-channel MOSFET transistors, thereby optimizing the voltage blocked by each region.

Abstract: Systems and methods are disclosed for manufacturing grounded gate cross-hair cells and standard cross-hair cells of fin field-effect transistors (finFETs). In one embodiment, a process may include forming gate trenches and gates on and parallel to row trenches in a substrate, wherein the gate trenches and gates are pitch-doubled such that four gate trenches are formed for every two row trenches. In another embodiment, a process may include forming gate trenches, gates, and grounded gates in a substrate, wherein the gate trenches and gates are formed such that three gate trenches are formed for every two row trenches.

Abstract: A power semiconductor structure with schottky diode is provided. In the step of forming the gate structure, a separated first polysilicon structure is also formed on the silicon substrate. Then, the silicon substrate is implanted with dopants by using the first polysilicon structure as a mask to form a body and a source region. Afterward, a dielectric layer is deposited on the silicon substrate and an open penetrating the dielectric layer and the first polysilicon structure is formed so as to expose the source region and the drain region below the body. The depth of the open is smaller than the greatest depth of the body. Then, a metal layer is filled into the open to electrically connect to the source region and the drain region.

Abstract: In according with the present invention, a semiconductor device is formed as follows. A contact insulation layer is deposited on the top surface of said silicon layer. A contact mask is applied and following with a dry oxide etching to remove the contact insulation layer from contact open areas. The silicon layer is tilt-angle implanted with a source dopant through the contact open areas and the source dopant is diffused to form source regions, thereby a source mask is saved. A dry silicon etch is carried out to form trenched source-body contacts in the contact open areas, penetrating through the source regions and extending into the body regions.

Abstract: A semiconductor power device comprises a plurality of power transistor cells each having a trenched gate disposed in a gate trench wherein the trenched gate comprising a shielding bottom electrode disposed in a bottom portion of the gate trench electrically insulated from a top gate electrode disposed in a top portion of the gate trench by an inter-electrode insulation layer. At least one of the transistor cells includes the shielding bottom electrode functioning as a source-connecting shielding bottom electrode electrically connected to a source electrode of the semiconductor power device and at least one of the transistor cells having the shielding bottom electrode functioning as a gate-connecting shielding bottom electrode electrically connected to a gate metal of the semiconductor power device.

Abstract: A semiconductor device having a semiconductor body comprising an active area and a termination structure surrounding the active area, and a method for the manufacture thereof. The invention particularly concerns a termination structure for such devices having trenched electrodes in the active area. The termination structure comprises a plurality of lateral trench-gate transistor devices connected in series and extending from the active area towards a peripheral edge of the semiconductor body. The lateral devices are arranged such that a voltage difference between the active area and the peripheral edge is distributed across the lateral devices. The termination structure is compact and features of the structure are susceptible for formation in the same process steps as features of the active area.

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 semiconductor structure is formed as follows. Trenches are formed in a semiconductor region and a shield electrode is formed in each trench. Gate electrodes are formed in a portion of the trenches that form an active region. Each gate electrode is disposed over the shield electrode and is isolated from the shield electrode by an inter-electrode dielectric. An interconnect layer is formed extending over the trenches. The interconnect layer is isolated from the gate electrodes in the active region by a dielectric layer and contacts the shield electrodes in a shield contact region separate from the active region. The interconnect layer contacts mesa surfaces between adjacent trenches in the shield contact region.

Abstract: In accordance with an embodiment a structure can include a monolithically integrated trench field-effect transistor (FET) and Schottky diode. The structure can include a first gate trench extending into a semiconductor region, a second gate trench extending into the semiconductor region, and a source region flanking a side of the first gate trench. The source region can have a substantially triangular shape, and a contact opening extending into the semiconductor region between the first gate trench and the second gate trench. The structure can include a conductor layer disposed in the contact opening to electrically contact the source region along at least a portion of a slanted sidewall of the source region, and the semiconductor region along a bottom portion of the contact opening. The conductor layer can form a Schottky contact with the semiconductor region.

Abstract: Power devices, and related process, where both gate and field plate trenches have multiple stepped widths, using self-aligned process steps.