Abstract: A semiconductor module having one or more silicon carbide diode elements mounted on a switching element is provided in which the temperature rise is reduced by properly disposing each of the diode elements on the switching element, to thereby provide a thermal dissipation path for the respective diode elements. The respective diode elements are arranged on a non-central portion of the switching element, to facilitate dissipation of the heat produced by each of the diode elements, whereby the temperature rise in the semiconductor module is reduced.

Abstract: An ESD protection device is described, which includes a P-body region, a P-type doped region, an N-type doped region and an N-sinker region. The P-body region is configured in a substrate. The P-type doped region is configured in the middle of the P-body region. The N-type doped region is configured in the P-body region and surrounds the P-type doped region. The N-sinker region is configured in the substrate and surrounds the P-body region.

Abstract: Ultra-low drain-source resistance power MOSFET. In accordance with an embodiment of the preset invention, a semiconductor device comprises a plurality of trench power MOSFETs. The plurality of trench power MOSFETs is formed in a second epitaxial layer. The second epitaxial layer is formed adjacent and contiguous to a first epitaxial layer. The first epitaxial layer is formed adjacent and contiguous to a substrate highly doped with red Phosphorous. The novel red Phosphorous doped substrate enables a desirable low drain-source resistance.

Abstract: A substrate section that is at least partially fabricated to include contact elements and materials. The substrate section includes doped regions that have a heavily doped N-type region and a heavily doped P-type region adjacent to one another. An exterior surface of the substrate has a topography that includes a light-transparent region in which light, from a light source, is able to reach a surface of the substrate. An application of light onto the light transparent region is sufficient to cause a voltage potential to form across a junction of the heavily doped regions. The substrate section may further comprise one or more electrical contacts, positioned on the substrate section to conduct current, resulting from the voltage potential created with application of light onto the light transparent region, to a circuit on the semiconductor substrate.

Abstract: A method and apparatus for use in improving the linearity characteristics of MOSFET devices using an accumulated charge sink (ACS) are disclosed. The method and apparatus are adapted to remove, reduce, or otherwise control accumulated charge in SOI MOSFETs, thereby yielding improvements in FET performance characteristics. In one exemplary embodiment, a circuit having at least one SOI MOSFET is configured to operate in an accumulated charge regime. An accumulated charge sink, operatively coupled to the body of the SOI MOSFET, eliminates, removes or otherwise controls accumulated charge when the FET is operated in the accumulated charge regime, thereby reducing the nonlinearity of the parasitic off-state source-to-drain capacitance of the SOT MOSFET. In RF switch circuits implemented with the improved SOI MOSFET devices, harmonic and intermodulation distortion is reduced by removing or otherwise controlling the accumulated charge when the SOI MOSFET operates in an accumulated charge regime.

Abstract: A termination structure with multiple embedded potential spreading capacitive structures (TSMEC) and method are disclosed for terminating an adjacent trench MOSFET atop a bulk semiconductor layer (BSL) with bottom drain electrode. The BSL has a proximal bulk semiconductor wall (PBSW) supporting drain-source voltage (DSV) and separating TSMEC from trench MOSFET. The TSMEC has oxide-filled large deep trench (OFLDT) bounded by PBSW and a distal bulk semiconductor wall (DBSW). The OFLDT includes a large deep oxide trench into the BSL and embedded capacitive structures (EBCS) located inside the large deep oxide trench and between PBSW and DBSW for spatially spreading the DSV across them. In one embodiment, the EBCS contains interleaved conductive embedded polycrystalline semiconductor regions (EPSR) and oxide columns (OXC) of the OFLDT, a proximal EPSR next to PBSW is connected to an active upper source region and a distal EPSR next to DBSW is connected to the DBSW.

Abstract: According to one embodiment, a semiconductor device, includes an element unit including a vertical-type MOSFET, the vertical-type MOSFET in including a first semiconductor layer, a second semiconductor layer, a third semiconductor layer, a fourth semiconductor layer, a fifth semiconductor layer sequentially stacked in order, an impurity concentration of the second semiconductor layer being lower than the first semiconductor layer, an insulator covering inner surfaces of a plurality of trenches, the adjacent trenches being provided with a first interval in between, and a diode unit including basically with the units of the element unit, the adjacent trenches being provided with a second interval in between, the second interval being larger than the first interval.

Abstract: Power semiconductor devices, and related methods, where majority carrier flow is divided into paralleled flows through two drift regions of opposite conductivity types.

Abstract: Provided is a power semiconductor device including a semiconductor substrate, in which a current flows in a thickness direction of the semiconductor substrate. The semiconductor substrate includes a resistance control structure configured so that a resistance to the current becomes higher in a central portion of the semiconductor substrate than a peripheral portion of the semiconductor substrate.

Abstract: A field effect transistor is provided having a reduced drain capacitance per unit gate width. A gate electrode 21 (G) having a plurality of sides is formed in first-conductivity first semiconductor region 14. Drain region 18D (D) is formed inside the gate electrode, and source regions 18S (S) are formed in respective regions outside the plurality of sides in widths that do not reduce the corresponding channel widths of the drain region. The gate electrode is formed along all the plurality of sides of the drain region in order to form a transistor.

Abstract: In view of achieving a cost reduction of an antenna switch, a technique is provided which can reduce harmonic distortion generated in the antenna switch as much as possible in particular even when the antenna switch is comprised of a field effect transistor formed over a silicon substrate. Each of a TX series transistor, an RX series transistor, and an RX shunt transistor is comprised of a low voltage MISFET, while a TX shunt transistor is comprised of a high voltage MISFET. Thus, by reducing the number of serial connections of the high voltage MISFETs constituting the TX shunt transistor, the nonuniformity of the voltage amplitudes applied to the respective serially-coupled high voltage MISFETs is suppressed. As a result, the generation of high-order harmonics can be suppressed.

Abstract: A semiconductor device is provided. The semiconductor device includes a semiconductor body with a base region and a first electrode arranged on a main horizontal surface of the semiconductor body. The semiconductor body further includes an IGBT-cell with a body region forming a first pn-junction with the base region, and a diode-cell with an anode region forming a second pn-junction with the base region. A source region in ohmic contact with the first electrode and an anti-latch-up region in ohmic contact with the first electrode are, in a vertical cross-section, only formed in the IGBT-cell. The anti-latch-up region has higher maximum doping concentration than the body region. Further a reverse conducting IGBT is provided.

Abstract: A vertical trench LDMOS transistor includes a semiconductor layer of a first conductivity type; a first trench formed in the semiconductor layer and filled with a trench dielectric and a trench gate is formed in the first trench; a body region of a second conductivity type formed in the semiconductor layer adjacent the first trench; a source region formed in the body region and adjacent the first trench; a planar gate insulated from the semiconductor layer by a second gate dielectric layer and overlying the body region; and a drain drift region formed in the semiconductor layer. The planar gate forms a lateral channel in the body region between the source region and the drain drift region, and the trench gate in the first trench forms a vertical channel in the body region along the sidewall of the first trench between the source region and the semiconductor layer.

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: An IGBT with almost no tail during turning-off is formed by connection of both the base and the emitter of the BJT of the IGBT at the bottom of the chip to two regions in an area of the top surface of the chip. The two regions keep non-depleted even under a maximum voltage being applied across the collector and the base of the BJT. The current through the two regions can be controlled by a gate voltage of a place close to the active region of the MISFET of the IGBT through a surface voltage-sustaining region. The injection efficiency of minorities of the IGBT can thus be controlled.

Abstract: A hybrid device including a silicon based MOSFET operatively connected with a GaN based device.

Abstract: A high breakdown voltage semiconductor device, in which a semiconductor layer is formed on a semiconductor substrate across a dielectric layer, includes a drain layer on the semiconductor layer, a buffer layer formed so as to envelop the drain layer, a source layer, separated from the drain layer, and formed so as to surround a periphery thereof, a well layer formed so as to envelop the source layer, and a gate electrode formed across a gate insulating film on the semiconductor layer, wherein the planar shape of the drain layer 113 and buffer layer is a non-continuous or continuous ring.

Abstract: A trench gate semiconductor device is disclosed which has a trench gate structure including an insulator in the upper portion of a first trench, the insulator being on a gate electrode; a source region having a lower end surface positioned lower than the upper surface of the gate electrode; a second trench in the surface portion of a semiconductor substrate between the first trenches, the second trench having a slanted inner surface providing the second trench with the widest trench width at its opening and a bottom plane positioned lower than the lower end surface of the source region, the slanted inner surface being in contact with the source region; and a p-type body-contact region in contact with the slanted inner surface of the second trench. The trench gate semiconductor device and its manufacturing method facilitate increasing the channel density and lowering the body resistance of the parasitic BJT.

Abstract: A semiconductor structure is provided, which includes multiple sections arranged along a longitudinal axis. Preferably, the semiconductor structure comprises a middle section and two terminal sections located at opposite ends of the middle section. A semiconductor core having a first dopant concentration preferably extends along the longitudinal axis through the middle section and the two terminal sections. A semiconductor shell having a second, higher dopant concentration preferably encircles a portion of the semiconductor core at the two terminal sections, but not at the middle section, of the semiconductor structure. It is particularly preferred that the semiconductor structure is a nanostructure having a cross-sectional dimension of not more than 100 nm.

Abstract: An ultra-high voltage device has a high voltage path established from a high voltage N-well through a first metal layer to a second metal layer, and a contact plug electrically connected between the high voltage N-well and the first metal layer. The contact plug has a distributed structure on a horizontal layout to improve the uniformity of the ultra-high voltage device such that the current in the high voltage path will be more uniform distributed so as to avoid the localized heat concentration caused by non-uniform current distribution that would damage the ultra-high voltage device. Multiple fuse apparatus are preferably connected to the first metal layer individually. Each the fuse apparatus includes a poly fuse to be burnt down when an over-load current flows therethrough.

Abstract: A semiconductor power device includes a substrate, a first semiconductor layer on the substrate, a second semiconductor layer on the first semiconductor layer, and a third semiconductor layer on the second semiconductor layer. At least a recessed epitaxial structure is disposed within a cell region and the recessed epitaxial structure may be formed in a pillar or stripe shape. A first vertical diffusion region is disposed in the third semiconductor layer and the recessed epitaxial structure is surrounded by the first vertical diffusion region. A source conductor is disposed on the recessed epitaxial structure and a trench isolation is disposed within a junction termination region surrounding the cell region. In addition, the trench isolation includes a trench, a first insulating layer on an interior surface of the trench, and a conductive layer filled into the trench, wherein the source conductor connects electrically with the conductive layer.

Abstract: According to the embodiments, a semiconductor device using SiC and having a high breakdown voltage, a low on-resistance, and excellent reliability is provided.

Abstract: Improved MOSFET structures and processes, where multiple polysilicon embedded regions are introduced into the n+ source contact area. A top poly Field Plate is used to shield the electric field from penetrating into the channel, so that a very short channel can be used without jeopardizing the device drain-source leakage current. A bottom poly Field Plate is used to modulate the electric field distribution in the drift region such that a more uniform field distribution can be obtained.

Abstract: A method is disclosed for forming a patterned thick metallization atop a semiconductor chip wafer. The method includes fabricating a nearly complete semiconductor chip wafer ready for metallization; depositing a bottom metal layer of sub-thickness TK1 together with its built-in alignment mark using a hot metal process; depositing a top metal layer of sub-thickness TK2 using a cold metal process thus forming a stacked thick metallization of total thickness TK=TK1+TK2; then, use the built-in alignment mark as reference, patterning the stacked thick metallization. A patterned thick metallization is thus formed with the advantages of better metal step coverage owing to the superior step coverage nature of the hot metal process as compared to the cold metal process; and lower alignment error rate owing to the lower alignment signal noise nature of the cold metal process as compared to the hot metal process.

Abstract: A body contact layer 18 is formed on the side of a recessed structure 17 as well as in the bottom of the recessed structure 17, so that a contact area between the body contact layer 18 and a well layer 12 is increased and the amount of dopant implanted to the body contact layer 18 is suppressed.

Abstract: A method of forming a power MOSFET is described. An epitaxial layer of first conductivity type is formed on a substrate of first conductivity type. A body layer of second conductivity type is formed in the epitaxial layer. A plurality of mask patterns are formed on the substrate. A plurality of trenches are formed in the body layer and the epitaxial layer between the mask patterns. An oxide layer is formed on surfaces of the trenches. A conductive layer is formed in the trenches. A trimming process is performed to the mask patterns to reduce the line width of each mask pattern. Two source regions of first conductivity type are formed in the body layer beside each trench by using the trimmed mask patterns as a mask. A plurality of dielectric patterns are formed on the conductive layer and between the trimmed mask patterns. The trimmed mask patterns are removed.

Abstract: A problem associated with n-channel power MOSFETs and the like that the following is caused even by relatively slight fluctuation in various process parameters is solved: source-drain breakdown voltage is reduced by breakdown at an end of a p-type body region in proximity to a portion in the vicinity of an annular intermediate region between an active cell region and a chip peripheral portion, arising from electric field concentration in that area. To solve this problem, the following measure is taken in a power semiconductor device having a superjunction structure in the respective drift regions of a first conductivity type of an active cell region, a chip peripheral region, and an intermediate region located therebetween: the width of at least one of column regions of a second conductivity type comprising the superjunction structure in the intermediate region is made larger than the width of the other regions.

Abstract: According to one embodiment, a semiconductor device includes a first and a second semiconductor layer of a first conductivity type, a third semiconductor layer of a second conductivity type, a source region of the first conductivity type, a first and a second main electrode, trench gates, a first and a second contact region. The third semiconductor layer is provided on the second semiconductor layer provided on the first semiconductor layer. The first main electrode is electrically connected to the first semiconductor layer. The second main electrode is electrically connected to the source region provided on the third semiconductor layer. The trench gates are provided from the third semiconductor layer to the second semiconductor layer. The first and second contact regions electrically connect the second main electrode and the third semiconductor layer. An opening area of the second contact hole is smaller than that of the first contact hole.

Abstract: A semiconductor device includes: a semiconductor substrate configured to include a plurality of trenches therein; a plurality of buried bit lines each configured to fill a portion of each trench; a plurality of active pillars each formed in an upper portion of each buried bit line; a plurality of vertical gates each configured to surround each active pillar; and a plurality of word lines configured to couple neighboring vertical gates with each other.

Abstract: An embodiment of a process for manufacturing an electronic device on a semiconductor body of a material with wide forbidden bandgap having a first conductivity type.

Abstract: An integrated device includes a semiconductor body, in which an STI insulation structure is formed, which delimits laterally first active areas and at least one second active area, respectively, in a low-voltage region and in a power region of the semiconductor body. The integrated device moreover includes low-voltage CMOS components, accommodated in the first active areas, and a power component in the second active area. The power component has a source region, a body region, a drain-contact region, and at least one field-insulating region, set between the body region and the drain-contact region. The field-insulating region is provided entirely on the semiconductor body.

Abstract: A semiconductor device includes a first semiconductor region and a second semiconductor region provided on a main surface of a substrate, being apart from each other and having first conductivity; a third semiconductor region provided between the first semiconductor region and the second semiconductor region and having second conductivity opposite to the first conductivity; a fourth semiconductor region provided on a main surface of the substrate, connected to the third semiconductor region, manufactured together with the third semiconductor region in the same manufacturing process, and having the conductivity same as that of the third semiconductor region; and trenches made on the main surface of the fourth semiconductor region and having a depth smaller than a junction depth of the fourth semiconductor region.

Abstract: The present invention provides a semiconductor power device including a substrate, an epitaxial layer disposed on the substrate and having at least a first trench and a second trench, a gate structure disposed in the first trench, and a termination structure disposed in the second trench. The gate structure includes a gate electrode, a gate dielectric layer disposed on an upper sidewall of the first trench and between the gate electrode and the epitaxial laver, and a shield electrode disposed under the gate electrode. The termination structure includes a termination electrode and a dielectric layer disposed between the termination electrode and a sidewall of the second trench. The termination electrode and the shield electrode are connected to each other. In addition, a body region is disposed in the epitaxial layer, and the second trench is only surrounded by the body region.

Abstract: Provided are a semiconductor device and a method of fabricating the semiconductor device.

Abstract: A semiconductor device includes: a semiconductor substrate having a first conductivity type; a well having a second conductivity type and provided inside the semiconductor substrate; a first impurity region having the first conductivity type and provided within the well; a second impurity region having the second conductivity type, provided inside the well and away from the first impurity region; and a third impurity region having a first conductivity type, provided surrounding the well and away from the second impurity region. In this semiconductor device, the well is formed to be deeper than the first impurity region, the second impurity region, and the third impurity region, in a thickness direction of the semiconductor substrate; and a minimum distance between the first impurity region and the second impurity region is smaller than a minimum distance between the second impurity region and the third impurity region.

Abstract: An inverter for driving a motor includes a plurality of power semiconductor devices. The plurality of power semiconductor devices include a resistance electrically connected between a collector and an emitter of an IGBT element. Each of the power semiconductor devices forms any one of a U-phase arm, a V-phase arm and a W-phase arm of the inverter. As a result, a discharge resistance is built in the inverter, and therefore, it is not required to prepare the discharge resistance separately. Thus, the number of components required for a motor drive apparatus can be decreased and the number of operation steps can be reduced.

Abstract: A semiconductor device having a super junction and a method of manufacturing the semiconductor device capable of obtaining a high breakdown voltage are provided, whereby charge balance of the super junction is further accurately controlled in the semiconductor device that is implemented by an N-type pillar and a P-type pillar. The semiconductor device includes a semiconductor substrate; and a blocking layer including a first conductive type pillar and a second conductive type pillar that extend in a vertical direction on the semiconductor substrate and that are alternately arrayed in a horizontal direction, wherein, in the blocking layer, a density profile of a first conductive type dopant may be uniform in the horizontal direction, and the density profile of the first conductive type dopant may vary in the vertical direction.

Abstract: Power semiconductor devices in which insulated empty space zones are used for field-shaping regions, in place of dielectric bodies previously used. Optionally permanent charge is added at the interface between the insulated empty space zone and an adjacent semiconductor drift region.

Abstract: In an ultra high voltage lateral DMOS-type device (UHV LDMOS device), a central pad that defines the drain region is surrounded by a racetrack-shaped source region with striations of alternating n-type and p-type material radiating outwardly from the pad to the source to provide for an adjustable snapback voltage.

Abstract: The present application discloses new approaches to integrated power. Two new classes of structures each provide an integrated phase leg, in a process which can easily be integrated with low-voltage and/or peripheral circuits: in one class of disclosed structures, a lateral PMOS device is combined with an NMOS device which has predominantly vertical current flow. In another class of embodiments, a predominantly vertical n-channel device is used for the low-side switch, in combination with a lateral n-channel device. In either case, the common output node is preferably brought out at a backside contact. This device structure is advantageously used to construct complete power supply and/or voltage conversions circuits on a single chip (perhaps connected to external passive reactances).

Abstract: A main FET and one or more sense FETs are formed in a common substrate. The main FET and sense FET(s) include a source terminal, a gate terminal and a drain terminal. The common gate pad connects the gate terminals of the main FET and sense FET(s). An electrical isolation may be between the gate terminals of the main FET and the sense FET(s). A sense pad in electrical contact with the source of the one or more sense FETs does not overlap an area of the device containing the sense FET(s). It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: Exemplary power semiconductor devices with features providing increased breakdown voltage and other benefits are disclosed.

Abstract: A power device includes a semiconductor region which in turn includes a plurality of alternately arranged pillars of first and second conductivity type. Each of the plurality of pillars of second conductivity type further includes a plurality of implant regions of the second conductivity type arranged on top of one another along the depth of pillars of second conductivity type, and a trench portion filled with semiconductor material of the second conductivity type directly above the plurality of implant regions of second conductivity type.

Abstract: In general, according to one embodiment, a semiconductor device includes a first electrode, a first and a second semiconductor layer of a first conductivity type, a third semiconductor layer of a second conductivity type, a fourth semiconductor layer of the first conductivity type in this order. A device region includes a gate electrode inside a first trench. A second trench having a ring-shaped structure forms a first region penetrating through the fourth and third semiconductor layers to the second semiconductor layer and including the device region inside and a second region surrounding the first region outside. A first opening is provided between adjacent ones of the first trenches. A second opening having a wider width than the first opening is provided in the first region outside the device region. A second electrode is electrically connected to the third and fourth semiconductor layers through the first and second openings.

Abstract: In a power IC device, a surface layer channel CMOS transistor and a trench power MOS transistor are formed on the same chip. In one embodiment, a source region of the trench power MOS transistor is arranged at the same level as a gate electrode of the surface layer channel CMOS transistor. Thus, the power IC device and a method for manufacturing the power IC device are provided for reducing manufacturing cost in the case of forming the trench power MOS transistor and the surface layer channel CMOS transistor on the same chip.

Abstract: An electronic device can include a buried conductive region, a buried insulating layer over the buried conductive region, and a semiconductor layer disposed over the buried insulating layer, wherein the semiconductor layer has a primary surface and an opposing surface, and the buried conductive region is disposed closer to the opposing surface than to the primary surface. The electronic device can also include a current-carrying electrode of a first transistor, wherein the current carrying electrode is disposed along the primary surface and spaced apart from the buried conductive layer. The electronic device can also include a vertical conductive structure extending through the buried insulating layer, wherein the vertical conductive structure is electrically connected to the current-carrying electrode and the buried conductive region.

Abstract: An electronic device can include a first well region of a first conductivity-type and a second well region of a second conductivity-type and abutting the first well region. The first conductivity-type and the second conductivity type can be opposite conductivity types. In an embodiment, an insulator region can extend into the first well region, wherein the insulator region and the first well region abut and define an interface, and, from a top view, the insulator region can include a first feature extending toward the first interface, and the insulator region can define a first space bounded by the first feature, wherein a dimension from a portion of the first feature closest to the first interface is at least zero. A gate structure can overlie an interface between the first and second well regions.

Abstract: A power semiconductor device which includes a gate contact on one surface thereof connected to a gate bus on another opposing surface thereof using a conductive body extending through a via between the two surfaces of the device.

Abstract: Electrically isolated, deep trench isolation (DTI) structures, are formed in a wafer, and a portion of the DTI structures are converted to electrically connected structures to provide a shielding function, or to provide connection to deep buried layers. In one aspect, DTI structures include a polysilicon filling over a liner layer disposed on the inner surface of a deep trench, the polysilicon is removed by isotropic etching, and the deep trench is re-filled with a conductive material. Alternatively, the polysilicon filling remains and a contact is formed to provide an electrical connection to the polysilicon. In another aspect, a deep trench is disposed in the wafer such that a lower portion thereof is located within a deep buried layer, and after the polysilicon is removed, an anisotropic etch removes a portion of the deep trench liner from the bottom of the deep trench, thereby allowing a tungsten deposition to make electrical contact with the deep buried layer.

Abstract: A power LDMOS device including a substrate, source and drain regions, gates and trench insulating structures is provided. The substrate has a finger tip area, a finger body area and a palm area. The source regions are in the substrate in the finger body area and further extend to the finger tip area. The neighboring source regions in the finger tip area are connected. The outmost two source regions further extend to the palm area and are connected. The drain regions are in the substrate in the finger body area and further extend to the palm area. The neighboring drain regions in the palm area are connected. The source and drain regions are disposed alternately. A gate is disposed between the neighboring source and drain regions. The trench insulating structures are in the substrate in the palm area and respectively surround ends of the drain regions.