Abstract: A MOSFET includes a semiconductor substrate having a trench formed in a main surface, a gate oxide film, a gate electrode, and a source interconnection. A semiconductor substrate includes an n-type drift layer and a p-type body layer. The trench is formed to penetrate the body layer and to reach the drift layer. The trench includes an outer peripheral trench arranged to surround an active region when viewed two-dimensionally. On the main surface opposite to the active region when viewed from the outer peripheral trench, a potential fixing region where the body layer is exposed is formed. The source interconnection is arranged to lie over the active region when viewed two-dimensionally. The potential fixing region is electrically connected to the source interconnection.

Abstract: According to one embodiment, a semiconductor device includes a first semiconductor region of a first conductivity type, a first control electrode, a first electrode, a second control electrode, a second semiconductor region of a second conductivity type, a third semiconductor region of the first conductivity type, and a first insulating film. The first control electrode is provided on or above the first semiconductor region. The first electrode is provided on the first control electrode. The second control electrode is provided on or above the first semiconductor region and includes a first portion which is beside the first control electrode and a second portion which is provided on the first portion and beside the first electrode. The second semiconductor region is provided on the first semiconductor region. A boundary between the first semiconductor region and the second semiconductor region is above the lower end of the first electrode.

Abstract: A semiconductor device has a semiconductor substrate and a breakdown voltage adjusting first conductivity type low concentration region provided on the semiconductor substrate. A second conductivity type high concentration region is provided near a surface within the breakdown voltage adjusting first conductivity type low concentration region so as to be surrounded by the first conductivity type low concentration region but not surrounded by any low concentration region other than the first conductivity type low concentration region. A first conductivity type high concentration region is provided on the surface within the breakdown voltage adjusting first conductivity type low concentration region without being held in contact with the second conductivity type high concentration region.

Abstract: A circuit configuration and methods for controlling parameters of a bipolar junction transistor (BJT) fabricated on a substrate. A bias voltage is electrically coupled to the substrate and can be adjusted to alter the working parameters of a target BJT.

Abstract: A multi-gate transistor device includes a substrate, a fin structure extending along a first direction formed on the substrate, a gate structure extending along a second direction formed on the substrate, a drain region having a first conductivity type formed in the fin structure, a source region having a second conductivity type formed in the fin structure, and a first pocket doped region having the first conductivity type formed in and encompassed by the source region. The first conductivity type and the second conductivity type are complementary to each other.

Abstract: A semiconductor device includes a drift zone of a first conductivity type in a semiconductor body. Controllable cells are configured to form a conductive channel connected with the drift zone in a first state. First zones of the first conductivity type as well as second zones and a third zone of a complementary second conductivity type are between the drift zone and a rear side electrode, respectively. The first, second and third zones directly adjoin the rear side electrode. The third zone is larger and has a lower mean emitter efficiency than the second zones.

Abstract: A semiconductor device includes a semiconductor layer made of a wide bandgap semiconductor and including a gate trench; a gate insulating film formed on the gate trench; and a gate electrode embedded in the gate trench to be opposed to the semiconductor layer through the gate insulating film. The semiconductor layer includes a first conductivity type source region; a second conductivity type body region; a first conductivity type drift region; a second conductivity type first breakdown voltage holding region; a source trench passing through the first conductivity type source region and the second conductivity type body region from the front surface and reaching a drain region; and a second conductivity type second breakdown voltage region selectively formed on an edge portion of the source trench where the sidewall and the bottom wall thereof intersect with each other in a parallel region of the source trench.

Abstract: In one embodiment, a semiconductor device includes a first semiconductor layer of a first conductivity type having first and second faces, and a second semiconductor layer of a second conductivity type disposed above the first face of the first semiconductor layer. The device further includes control electrodes facing the first and second semiconductor layers via insulating layers, and extending to a first direction parallel to the first face of the first semiconductor layer, and third semiconductor layers of the first conductivity type and fourth semiconductor layers of the second conductivity type alternately disposed along the first direction above the second semiconductor layer. The device further includes fifth semiconductor layers of the first conductivity type disposed below the second semiconductor layer or disposed at positions surrounded by the second semiconductor layer, the fifth semiconductor layers being arranged separately from one another along the first direction.

Abstract: An IGBT device includes one or more trench gates disposed over a semiconductor substrate and a floating body region of the first conductivity type disposed between two neighboring trench gates and between a semiconductor substrate and a heavily doped top region of the second conductivity type. A body region of the first conductivity type disposed over the top region has a doping concentration higher than that of the floating body region of the first conductivity type. It is emphasized that this abstract is provided to comply with 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: A field limiting regions are arranged in the upper surface of a semiconductor region in the peripheral region and connected to upper portions of at least some of columnar regions. An insulating film is provided on the semiconductor region in the peripheral region and covering a field limiting region. A coupling plate electrode is provided above a pair of the field limiting regions adjacent to each other in a direction from a boundary between the element region and the peripheral region to an outer edge of the peripheral region. The joint field regions are in contact with one of the pair of field limiting regions on a boundary side in an opening formed in the insulating film, and reaching the other one of the pair of the field limiting regions on an outer edge side with the insulating film interposed therebetween.

Abstract: An IGBT has layers between emitter and collector sides. The layers include a collector layer on the collector side, a drift layer, a base layer of a second conductivity type, a first source region arranged on the base layer towards the emitter side, a trench gate electrode arranged lateral to the base layer and extending deeper into the drift layer than the base layer, a well arranged lateral to the base layer and extending deeper into the drift layer than the base layer, an enhancement layer surrounding the base layer so as to completely separate the base layer from the drift layer and the well, an electrically conducting layer covering the well and separated from the well by a second electrically insulating layer, and a third insulating layer having a recess on top of the electrically conducting layer such that the electrically conducting layer electrically contacts a emitter electrode.

Abstract: In a semiconductor device a barrier region is sandwiched between a drift region and a charge carrier transfer region. The barrier and charge carrier transfer regions form a pn junction. The barrier and drift regions form a homojunction. A mean impurity concentration in the barrier region is at least ten times as high as an impurity concentration in the drift region. A control structure is arranged to form an inversion layer in the drift and barrier regions in an inversion state. No inversion layer is formed in the drift and barrier regions in a non-inversion state.

Abstract: A reverse conducting IGBT that includes an insulated gate; a semiconductor layer having a first conductivity type drift region, a second conductivity type body region, a first conductivity type emitter region, and a second conductivity type intermediate region; and an emitter electrode provided on a surface of the semiconductor layer. The first conductivity type drift region of the semiconductor layer contacts the insulated gate. The second conductivity type body region of the semiconductor layer is provided on the drift region and contacts the insulated gate. The first conductivity type emitter region of the semiconductor layer is provided on the body region and contacts the insulated gate. The second conductivity type intermediate region of the semiconductor layer is provided on the emitter region and is interposed between the emitter region and the emitter electrode.

Abstract: An IGBT has layers between emitter and collector sides. The layers include a drift layer, a base layer electrically contacting an emitter electrode and separated from the drift layer, a first source region arranged on the base layer towards the emitter side and electrically contacting the emitter electrode, and a first trench gate electrode arranged lateral to the base layer and separated from the base layer, the first source region and the drift layer by a first insulating layer. A channel exits between the emitter electrode, the first source region, the base layer and the drift layer. A second insulating layer is arranged on top of the first trench gate electrode. An enhancement layer separates the base layer from the drift layer in a plane parallel to the emitter side. A grounded gate electrode includes a second, grounded trench gate electrode and an electrically conducting layer.

Abstract: A compound semiconductor device includes a nitride semiconductor stacked structure including a carrier transit layer and a carrier supply layer; a source electrode and a drain electrode provided over the nitride semiconductor stacked structure; a gate electrode provided between the source electrode and the drain electrode, over the nitride semiconductor stacked structure; a field plate provided at least partially between the gate electrode and the drain electrode; and a plurality of insulation films and formed over the nitride semiconductor stacked structure, wherein a number of interfaces of the plurality of insulation films is smaller between the field plate and the drain electrode than in the vicinity of the gate electrode.

Abstract: A p anode layer (2) is formed on one main surface of an n? drift layer (1). An n+ cathode layer (3) having an impurity concentration more than that of the n? drift layer (1) is formed on the other main surface of the n? drift layer (1). An anode electrode (4) is formed on the surface of the p anode layer (2). A cathode electrode (5) is formed on the surface of the n+ cathode layer (3). An n-type broad buffer region (6) that has a net doping concentration more than the bulk impurity concentration of a wafer and less than that of the n+ cathode layer (3) and the p anode layer (2) is formed in the n? drift layer (1). The resistivity ?0 of the n? drift layer (1) satisfies 0.12V0??0?0.25V0 with respect to a rated voltage V0. The total amount of the net doping concentration of the broad buffer region (6) is equal to or more than 4.8×1011 atoms/cm2 and equal to or less than 1.0×1012 atoms/cm2.

Abstract: In an IGBT, defects generated by ion implantation for introduction of the P-type collector region or N-type buffer region into the N?-type drift region near the N-type buffer region remain to improve the switching speed, however the leak current increases by bringing a depletion layer into contact with the crystal defects at the off time. To avoid this, an IGBT is provided which includes an N-type buffer region having a higher concentration than that of an N?-type drift region and being in contact with a P-type on its backside, and a defect remaining region provided near the boundary between the N-type buffer region and the N?-type drift region. The N?-type drift region located on the front surface side with respect to the defect remaining region is provided with an N-type field stopping region having a higher concentration than that of the N?-type drift region.

Abstract: A semiconductor device includes a first semiconductor region of a first conductivity type, a second semiconductor region of a second conductivity type on the first semiconductor region, a third semiconductor region of the first conductivity type on the second semiconductor region, a control electrode disposed within and insulated from the first, second, and third semiconductor regions, a first electrode electrically connected with the second and third semiconductor regions, a second electrode, and a fourth semiconductor region of the second conductivity type between the second electrode and the first semiconductor region. The fourth semiconductor region includes a first portion having a first dopant concentration and a second portion having a second dopant concentration higher than the first dopant concentration, and a contact area of the first portion with the second electrode is larger than a contact area of the second area with the second electrode.

Abstract: A transistor includes a device portion and a collector layer. The device portion is in a first side of a semiconductor substrate, and includes a gate and an emitter. The collector layer is on a second side of the semiconductor substrate, which is opposite to the first side. The collector layer is an impurity-doped epitaxial layer and has a doping profile with a non-normal distribution.

Abstract: A power semiconductor device may include: a first semiconductor layer having a first conductivity type; a second semiconductor layer formed on the first semiconductor layer, having a concentration of impurities higher than that of the first semiconductor layer, and having the first conductivity type; a third semiconductor layer formed on the second semiconductor layer and having a second conductivity type; a fourth semiconductor layer formed in an upper surface of the third semiconductor layer and having the first conductivity type; and trench gates penetrating from the fourth semiconductor layer into a portion of the first semiconductor layer and having gate insulating layers formed on surfaces thereof. The trench gates have a first gate, a second gate, and a third gate are sequentially disposed from a lower portion thereof, and the first gate, the second gate, and the third gate are insulated from each other by gate insulating films.

Abstract: A power semiconductor device may include a first semiconductor region having a first conductivity type, a second semiconductor region having a second conductivity type formed on an upper portion of the first semiconductor region, a third semiconductor region having a first conductivity type formed in an inner portion of an upper portion of the second semiconductor region, a trench gate formed to penetrate from the third semiconductor region to the first semiconductor region and including a first insulating layer formed on a surface thereof, and a second insulating layer formed in a lower portion of the trench gate.

Abstract: A power semiconductor device may include: an active region having a current flowing through a channel formed therein at the time of a turn-on operation of the power semiconductor device; an termination region formed in the vicinity of the active region; a plurality of trenches formed in a length direction of the active region; a first conductivity type hole accumulating region formed below the channel in the active region; and a first conductivity type electric field limiting region formed in the termination region. The electric field limiting region is formed so as to at least partially cover a trench positioned at a boundary between the active region and the termination region.

Abstract: In the reverse-conducting IGBT according to the present invention, an n-type buffer layer surrounds a p-type collector layer. A p-type separation layer surrounds an n-type cathode layer. The n-type buffer layer separates the p-type collector layer and the p-type separation layer from each other. The p-type separation layer separates the n-type cathode layer and the n-type buffer layer from each other. Therefore, the present invention makes it possible to reduce snapback.

Abstract: A power semiconductor device may include: a first semiconductor region having a first conductivity type; a second semiconductor region having a second conductivity type and formed on the first semiconductor region; a third semiconductor region having the first conductivity type and formed in an upper portion of the second semiconductor region; a trench gate formed to penetrate from the third semiconductor region to the first semiconductor region, having a gate insulating layer formed on a surface thereof, and filled with a conductive material; and a fourth semiconductor region having the second conductivity type and formed to penetrate through the second semiconductor region.

Abstract: In a semiconductor device a barrier region is sandwiched between a drift region and a charge carrier transfer region. The barrier and charge carrier transfer regions form a pn junction. The barrier and drift regions form a homojunction. A mean impurity concentration in the barrier region is at least ten times as high as an impurity concentration in the drift region. A control structure is arranged to form an inversion layer in the drift and barrier regions in an inversion state. No inversion layer is formed in the drift and barrier regions in a non-inversion state.

Abstract: Disclosed herein are a power module package and a method of manufacturing the same. The power module package includes first and second semiconductor devices mounted on sides of first and second lead frames, ends of which are separated from each other, respectively, a support pin corresponding to a mounting position of the first semiconductor device and formed adjacent to a lower portion of the first lead frame, and a molding portion formed to cover portions of the first and second lead frames and the first and second semiconductor devices.

Abstract: A power semiconductor device may include: an active region having a current flowing through a channel formed therein at the time of a turn-on operation of the power semiconductor device; a termination region formed in the vicinity of the active region; a plurality of first trenches formed lengthwise in one direction in the active region; and at least one or more second trenches formed lengthwise in one direction in the termination region. The second trench has a depth deeper than that of the first trench.

Abstract: An insulated gate bipolar transistor having a gate electrode (7) and an emitter electrode (9) is provided in a transistor region. A termination region is arranged around the transistor region. A first N type buffer layer (18) is provided below an N type drift layer (1) in the transistor region. A P type collector layer (19) is provided below the first N type buffer layer (18). A second N type buffer layer (20) is provided below the N type drift layer (1) in the termination region. A collector electrode (21) is directly connected to the P type collector layer (19) and the second N type buffer layer (20). An impurity concentration of the second N type buffer layer (20) decreases as a distance from the collector electrode (21) decreases. The second N type buffer layer (20) does not form any ohmic contact with the collector electrode (21).

Abstract: In a method of further enhancing the performance of a narrow active cell IE type trench gate IGBT having the width of active cells narrower than that of inactive cells, it is effective to shrink the cells so that the IE effects are enhanced. However, when the cells are shrunk simply, the switching speed is reduced due to increased gate capacitance. A cell formation area of the IE type trench gate IGBT is basically composed of first linear unit cell areas having linear active cell areas, second linear unit cell areas having linear hole collector areas and linear inactive cell areas disposed therebetween.

Abstract: A semiconductor device includes a field effect transistor structure having source zones of a first conductivity type and body zones of a second conductivity type which is the opposite of the first conductivity type, the source zones adjoining a first surface of a semiconductor die comprising the source and the body zones. The semiconductor device further includes a dielectric layer adjoining the first surface and polysilicon plugs extending through openings in the dielectric layer and electrically connected to the source and the body zones. The polysilicon plugs have silicide crystallites in portions distant to the semiconductor die.

Abstract: An IGBT device includes one or more trench gates disposed over a semiconductor substrate and a floating body region of the first conductivity type disposed between two neighboring trench gates and between a semiconductor substrate and a heavily doped top region of the second conductivity type. A body region of the first conductivity type disposed over the top region has a doping concentration higher than that of the floating body region of the first conductivity type. It is emphasized that this abstract is provided to comply with 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: A semiconductor power device is provided, comprising a substrate of a first conductive type, a buffering layer of a second conductive type formed on the substrate, a voltage supporting layer formed on the buffering layer, and alternating sections of different conductive types formed at the substrate. The voltage supporting layer comprises first semiconductor regions of the first conductive type and second semiconductor regions of the second conductive type, wherein the first semiconductor regions and the second semiconductor regions are alternately arranged. The alternating section and the buffering layer form a segmented structure of alternated conductive types, which is used as an anode of the semiconductor device.

Abstract: A semiconductor device having a p base region and an n+ emitter region that come into contact with an emitter electrode and are selectively provided in a surface layer of an n? drift layer. A gate electrode is provided on a portion of the front surface of the n? drift layer which is interposed between the n+ emitter regions, with a gate insulating film interposed therebetween. In some exemplary embodiments, an n+ buffer layer and a p collector layer which have a higher impurity concentration than the n? drift layer are sequentially provided on a surface of the n? drift layer opposite to the front surface on which the n+ emitter region is provided. The impurity concentration of the n+ buffer layer is equal to or greater than 7×1016 cm?3 and equal to or less than 7×1017 cm?3. Accordingly, it is possible to obtain high field decay resistance.

Abstract: A semiconductor device includes a first conductivity-type drift layer, a second conductivity-type base layer formed in a front surface portion of the drift layer, a second conductivity-type collector layer formed in the drift layer and separated from the base layer, gate insulation layers formed on a surface of the base layer, gate electrodes individually formed on the gate insulation layers, an emitter layer formed in a front surface portion of the base layer, an emitter electrode electrically connected to the emitter layer and the base layer, and a collector electrode electrically connected to the collector layer. A rate of change in a gate voltage of a part of the gate electrodes is smaller than a rate of change in a gate voltage of a remainder of the gate electrodes. The emitter layer is in contact with only the gate insulation layers provided with the part of the gate electrodes.

Abstract: An object of the present invention is to provide a trench gate type IGBT achieving both retention of withstand voltage and lowering of ON-state voltage and to provide a method for manufacturing the trench gate type IGBT. The IGBT according to the present invention is an SJ-RC-IGBT which includes a drift layer having super junction structure, and includes an IGBT area and an FWD area on the rear surface. In the IGBT according to the present invention, a first drift layer has an impurity concentration of 1×1015 atms/cm3 or higher and lower than 2×1016 atms/cm3, and a thickness of 10 ?m or larger and smaller than 50 ?m; and that a buffer layer has an impurity concentration of 1×1015 atms/cm3 or higher and lower than 2×1016 atms/cm3, and a thickness of 2 ?m or larger and smaller than 15 ?m.

Abstract: A packaged semiconductor device comprising a package and a semiconductor device is described. The semiconductor device comprises a first and a second GND-pad bonded to one or more GND-pins with a first and a second bond wire respectively, a first functional pad bonded to a first functional pin with a third bond wire, a semiconductor layer of a P-type conductivity, a first semiconductor component and a second semiconductor component. The first semiconductor component is arranged to, when a transient current is applied to the first functional pin, divert at least part of the transient current to the first GND-pad from the first P-region to the first GND-pad via at least a first PN-junction. The second semiconductor component comprises a second N-type region of a terminal of the second semiconductor component associated with the first functional pad. The first GND-pad is in contact with a second P-type region. The second GND-pad is in contact with a third N-type region.

Abstract: According to one embodiment, a semiconductor device includes a first major electrode, a first semiconductor layer, a first conductivity-type base layer, a second conductivity-type base layer, a second semiconductor layer, a buried layer, a buried electrode, a gate insulating film, a gate electrode, and a second major electrode. The buried layer of the second conductivity type selectively is provided in the first conductivity-type base layer. The buried electrode is provided in a bottom portion of a trench which penetrates the second conductivity-type base layer to reach the buried layer. The buried electrode is in contact with the buried layer. The gate electrode is provided inside the gate insulating film in the trench. The second major electrode is provided on the second semiconductor layer and is electrically connected to the second semiconductor layer and the buried electrode.

Abstract: A power semiconductor device may include a first conductivity type first semiconductor region; a second conductivity type second semiconductor region formed on an upper portion of the first semiconductor region; a first conductivity type third semiconductor region formed in an upper inner side of the second semiconductor region; a trench gate formed to penetrate through a portion of the first semiconductor region from the third semiconductor region; and a first conductivity type fourth semiconductor region formed below the second semiconductor region while being spaced apart from the trench gate.

Abstract: A high-voltage insulated gate type power semiconductor device includes a low-concentration first conductivity type base layer; a plurality of trenches selectively formed with large intervals and narrow intervals provided alternately, in a front surface of the low-concentration first conductivity type base layer; a gate insulating film formed on a surface of each of the plurality of trenches; a gate electrode formed inside the gate insulating film; and a second conductivity type base layer selectively formed between the adjacent trenches sharing the narrow interval. The high-voltage insulated gate type power semiconductor device includes a high-concentration first conductivity type source layer selectively formed on a front surface of the second conductivity type base layer.

Abstract: In a semiconductor device, a trench includes a first trench that has an opening portion on a surface of a base layer, and a second trench that is communicated with the first trench and in which a distance between opposed side walls is greater than opposed side walls of the first trench and a bottom portion is located in a drift layer. A wall surface of a connecting portion of the second trench connecting to the first trench is rounded. Therefore, an occurrence of a large electrical field concentration in the vicinity of the connecting portion between the first trench and the second trench can be suppressed. Also, when electrons are supplied from a channel region to the drift layer, it is less likely that a flow direction of the electrons will be sharply changed in the vicinity of the connecting portion. Therefore, an on-state resistance can be reduced.

Abstract: A semiconductor device includes: a first semiconductor region; a second semiconductor region; a third semiconductor region; a fourth semiconductor region; an insulation film, which is arranged on an inner wall of a recess that extends from an upper surface of the fourth semiconductor region and reaches the second semiconductor region with penetrating the fourth semiconductor region and the third semiconductor region; a control electrode, which is arranged on the insulation film on a side surface of the recess and faces the third semiconductor region; a first main electrode, which is electrically connected to the first semiconductor region, and a second main electrode, which is electrically connected to the fourth semiconductor region, wherein a ratio of a width of the recess to a width of the third semiconductor region contacting the second main electrode is 1 or larger.

Abstract: A semiconductor device in which short circuit capability can be improved while decline in overall current capability is suppressed. In the semiconductor device, a plurality of IGBTs (insulated gate bipolar transistors) arranged in a row in one direction over the main surface of a semiconductor substrate include an IGBT located at an extreme end in the one direction and an IGBT located more centrally than the IGBT located at the extreme end. The current capability of the IGBT located at the extreme end is higher than the current capability of the IGBT located centrally.

Abstract: A fabrication method of a semiconductor device includes forming a mask insulating film having a specified thickness on the top surface of an n-type semiconductor substrate, forming an opening at a specified position in the mask insulating film, carrying out ion implantation with p-type impurity ions onto the top surface, removing a layer portion formed in the mask insulating film with the p-type impurities included by the ion implantation, and carrying out heat treatment to diffuse the p-type impurities implanted into the n-type semiconductor substrate from the opening to a depth, thereby forming the p-type isolation region.

Abstract: An IGBT includes at least one first type transistor cell, including a base region, a first emitter region, a body region, and a second emitter region. The body region is arranged between the first emitter region and the base region. The base region is arranged between the body region and the second emitter region. The IGBT further includes a gate electrode adjacent the body region and dielectrically insulated from the body region by a gate dielectric, and a base electrode adjacent the base region and dielectrically insulated from the base region by a base electrode dielectric. The base region has a first base region section adjoining the base electrode dielectric and a second base region section arranged between the second emitter region and the first base region section. A doping concentration of the first base region section is higher than a doping concentration of the second base region section.

Abstract: A semiconductor device includes an insulated gate bipolar transistor (IGBT) arrangement. The IGBT arrangement includes a first configuration region of emitter-side insulated gate bipolar transistor structures and a second configuration region of emitter-side insulated gate bipolar transistor structures. The first configuration region and the second configuration region are arranged at a main surface of a semiconductor substrate of the semiconductor device. Further, the IGBT arrangement includes a collector layer and a drift layer. The collector layer is arranged at a backside surface of the semiconductor substrate and the drift layer is arranged between the collector layer and the emitter-side IGBT structures of the first configuration region and the second configuration region. Additionally, the collector layer includes at least a first doping region laterally adjacent to a second doping region.

Abstract: A semiconductor device includes a first region of a first conductivity type, a collector electrode electrically connected to a first side of the first region, first and second gate electrodes and first and second conductor electrodes, each of the gate and conductor electrodes extending into the first region from a second side thereof that is opposite to the first side, an emitter electrode electrically connected to the conductor electrodes, and a second region of the first conductivity type, that is adjacent to the gate electrodes, electrically connected to the emitter electrode, and spaced from the first and second conductor electrodes.

Abstract: A semiconductor device includes an insulated gate bipolar transistor (IGBT) arrangement. The IGBT arrangement includes a carrier confinement reduction region laterally arranged between a cell region and a sensitive region. The IGBT arrangement is configured or formed so that the cell region has a first average density of free charge carriers in an on-state of the IGBT arrangement, the carrier confinement reduction region has a second average density of free charge carriers in the on-state of the IGBT arrangement and the sensitive region has a third average density of free charge carriers in the on-state of the IGBT arrangement. The first average density of free charge carriers is larger than the second average density of free charge carriers and the second average density of free charge carriers is larger than the third average density of free charge carriers.

Abstract: The present invention relates to a technique of semiconductor devices, and provides a semiconductor device, which uses two controllable current sources to control the electron current and the hole current of the voltage-sustaining region of a thyristor under conduction state, making the sum of the two currents from anode to cathode close to a saturated value under high voltage, thus avoiding the current crowding effect in local region and increasing the reliability of the device. Besides, it further provides a method of implementing the two current sources in the device and a method to improve the switching speed.

Abstract: A semiconductor device includes: a first semiconductor region; a second semiconductor region; a third semiconductor region; a fourth semiconductor region; an insulation film, which is arranged on an inner wall of a recess extending from an upper surface to the second semiconductor region; a control electrode, which is arranged on a region of the insulation film on a side surface of the recess; a first main electrode connected to the first semiconductor region; a second main electrode connected to the fourth semiconductor region; and a bottom electrode, which is arranged on the insulation film and is electrically connected to the second main electrode, and a length of the recess in an extension direction thereof is equal to or larger than a width of the recess, and the width of the recess is wider than an interval between the adjacent recesses.

Abstract: An IGBT includes a mesa section that extends between two cell trench structures from a first surface of a semiconductor portion to a layer section of the semiconductor portion. A source region, which is electrically connected to an emitter electrode, is formed in the mesa section. A doped region, which is separated from the source region by a body region of a complementary conductivity type, includes a first portion with a first mean net impurity concentration and a second portion with a second mean net impurity concentration exceeding at least ten times the first mean net impurity concentration. In the mesa section the first portion extends from the body region to the layer section. The second portions of the doped region virtually narrow the mesa sections in a normal on-state of the IGBT.