Abstract: A semiconductor device including vertical channel transistor and a method for forming the transistor, which can significantly decrease the resistance of a word line is provided. A vertical channel transistor includes a substrate including pillars each of which has a lower portion corresponding to a channel region. A gate insulation layer is formed over the substrate including the pillars. A metal layer having a low resistance is used for forming a surrounding gate electrode to decrease resistance of a word line. A barrier metal layer is formed between a gate insulation layer and a surrounding gate electrode so that deterioration of characteristics of the insulation layer is prevented. A world line is formed connecting gate electrodes formed over the barrier layer to surround the lower portion of each pillar.

Abstract: A method for forming an opening within a semiconductor material comprises forming a neck portion, a rounded portion below the neck portion and, in some embodiments, a protruding portion below the rounded portion. This opening may be filled with a conductor, a dielectric, or both. Embodiments to form a transistor gate, shallow trench isolation, and an isolation material separating a transistor source and drain are disclosed. Device structures formed by the method are also described.

Abstract: Embodiments of semiconductor devices and methods of their formation include providing a semiconductor substrate having a top surface, a bottom surface, an active region, and an edge region, and forming a gate structure in a first trench in the active region of the semiconductor substrate. A termination structure is formed in a second trench in the edge region of the semiconductor substrate. The termination structure has an active region facing side and a device perimeter facing side. The method further includes forming first and second source regions of the first conductivity type are formed in the semiconductor substrate adjacent both sides of the gate structure. A third source region is formed in the semiconductor substrate adjacent the active region facing side of the termination structure. The semiconductor device may be a trench metal oxide semiconductor device, for example.

Abstract: A semiconductor device includes a first region of a first conductivity type and a body region of a second conductivity type, the first conductivity type being different from the second conductivity type. The body region is disposed on a side of a first surface of the semiconductor substrate. The semiconductor device further includes a plurality of trenches arranged in the first surface of the substrate, the trenches extending in a first direction having a component perpendicular to the first surface. Doped portions of the second conductivity type are adjacent to a lower portion of a sidewall of the trenches. The doped portions are electrically coupled to the body region via contact regions. The semiconductor device further includes a gate electrode disposed in an upper portion of the trenches.

Abstract: A semiconductor device includes a semiconductor body having a first surface and a second surface opposite to the first surface. A superjunction structure in the semiconductor body includes drift regions of a first conductivity type and compensation structures alternately disposed in a first direction parallel to the first surface. Each of the charge compensation structures includes a first semiconductor region of a second conductivity type complementary to the first conductivity type and a first trench including a second semiconductor region of the second conductivity type adjoining the first semiconductor region. The first semiconductor region and the first trench are disposed one after another in a second direction perpendicular to the first surface.

Abstract: A semiconductor devices including non-volatile memories and methods of fabricating the same to improve performance thereof are provided. Generally, the device includes a memory transistor comprising a polysilicon channel region electrically connecting a source region and a drain region formed in a substrate, an oxide-nitride-nitride-oxide (ONNO) stack disposed above the channel region, and a high work function gate electrode formed over a surface of the ONNO stack. In one embodiment the ONNO stack includes a multi-layer charge-trapping region including an oxygen-rich first nitride layer and an oxygen-lean second nitride layer disposed above the first nitride layer. Other embodiments are also disclosed.

Abstract: A power MOSFET includes a semiconductor substrate with an upper surface, a cavity of a first depth in the substrate whose sidewall extends to the upper surface, a dielectric liner in the cavity, a gate conductor within the dielectric liner extending to or above the upper surface, body region(s) within the substrate of a second depth, separated from the gate conductor in a lower cavity region by first portion(s) of the dielectric liner of a first thickness, and source region(s) within the body region(s) extending to a third depth that is less than the second depth. The source region(s) are separated from the gate conductor by a second portion of the dielectric liner of a second thickness at least in part greater than the first thickness. The dielectric liner has a protrusion extending laterally into the gate conductor away from the body region(s) at or less than the third depth.

Abstract: A semiconductor device comprises a semiconductor substrate; a channel layer of at least one III-V semiconductor compound above the semiconductor substrate; a gate electrode above a first portion of the channel layer; a source region and a drain region above a second portion of the channel layer; and a dopant layer comprising at least one dopant contacting the second portion of the channel layer.

Abstract: After formation of a gate electrode, a source trench and a drain trench are formed down to an upper portion of a bottom semiconductor layer having a first semiconductor material of a semiconductor-on-insulator (SOI) substrate. The source trench and the drain trench are filled with at least with a second semiconductor material that is different from the first semiconductor material to form source and drain regions. A planarized dielectric layer is formed and a handle substrate is attached over the source and drain regions. The bottom semiconductor layer is thinned, and remaining portions of the bottom semiconductor layer are removed selective to the second semiconductor material, the buried insulator layer, and a shallow trench isolation structure. A contact level dielectric layer is deposited on surfaces of the source and drain regions that are distal from the gate electrode, and contact vias are formed through the contact level dielectric layer.

Abstract: A semiconductor device including a buried gate is disclosed. In the semiconductor device, a bit line contact contacts a top surface and lateral surfaces of an active region, such that a contact area between a bit line contact and the active region is increased and a high-resistivity failure is prevented from occurring in a bit line contact.

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 embodiment of a charge-balance power device formed in an epitaxial layer having a first conductivity type and housing at least two columns of a second conductivity type, which extend through the epitaxial layer. A first and a second surface region of the second conductivity type extend along the surface of the epitaxial layer on top of, and in contact with, a respective one of the columns, and a second and a third surface region of the first conductivity type extends within the first and the second surface region, respectively, facing the surface of the epitaxial layer. The columns extend at a distance from each other and are arranged staggered to one another with respect to a first direction and partially facing one another with respect to a second direction transversal to the first direction.

Abstract: A semiconductor device includes an active region having a first floating charge control structure and a termination region having a second floating charge control structure. The second floating charge control structure is at least twice as long as the first floating control structure.

Abstract: An exemplary embodiment of the present disclosure illustrates a trench power MOSFET which includes a base, a plurality of first trenches, and a plurality of second trenches. The base has an active region and a termination region, wherein the termination region surrounds the active region. The plurality of first trenches is disposed in the active region. The plurality of second trenches is disposed in the termination region, wherein the second trenches extend outward from the active region side. The second trenches have isolation layers and conductive material deposited inside, in which the isolation layers are respectively disposed in the inner surface of the second trenches. The disclosed trench power MOSFET having the second trenches disposed in the termination region can increase the breakdown voltage thereof while minimize the termination region area thereby reduce the associated manufacturing cost.

Abstract: A vertical-current-flow device includes a trench which includes an insulated gate and which extends down into first-conductivity-type semiconductor material. A phosphosilicate glass layer is positioned above the insulated gate and a polysilicon layer is positioned above the polysilicate glass layer. Source and body diffusions of opposite conductivity types are positioned adjacent to a sidewall of the trench. A drift region is positioned to receive majority carriers which have been injected by the source, and which have passed through the body diffusion. A drain region is positioned to receive majority carriers which have passed through the drift region. The gate is capacitively coupled to control inversion of a portion of the body region. As an alternative, a dielectric layer may be used in place of the doped glass where permanent charge is positioned in the dielectric layer.

Abstract: A method and structures are provided for implementing vertical transistors utilizing wire vias as gate nodes. The vertical transistors are high performance transistors fabricated up in the stack between the planes of the global signal routing wire, for example, used as vertical signal repeater transistors. An existing via or a supplemental vertical via between wire planes provides both an electrical connection and the gate node of the novel vertical transistor.

Abstract: A charge-balance power device formed in an epitaxial layer having a first conductivity type and housing at least two columnar structures of a second conductivity type, which extend through the epitaxial layer. A first surface region of the second conductivity type extends along the surface of the epitaxial layer on top of, and in contact with, the columns, and a second surface region of the first conductivity type extends within the first surface region, and also faces the surface of the epitaxial layer. The columns extend at a distance from one another from the first surface region so as to delimit between them an epitaxial portion that defines a current path so as to reduce the on-resistivity of the device.

Abstract: A semiconductor device (A1) includes a first n-type semiconductor layer (11), a second n-type semiconductor layer (12), a p-type semiconductor layer (13), a trench (3), an insulating layer (5), a gate electrode (41), and an n-type semiconductor region (14). The p-type semiconductor layer (13) includes a channel region that is along the trench (3) and in contact with the second n-type semiconductor layer (12) and the n-type semiconductor region (14). The size of the channel region in the depth direction x is 0.1 to 0.5 ?m. The channel region includes a high-concentration region where the peak impurity concentration is approximately 1×1018 cm?3. The semiconductor device A1 thus configured allows achieving desirable values of on-resistance, dielectric withstand voltage and threshold voltage.

Abstract: An SiC semiconductor device includes a substrate, a drift layer, a base region, a source region, a trench, a gate oxide film, a gate electrode, a source electrode and a drain electrode. The substrate has a Si-face as a main surface. The source region has the Si-face. The trench is provided from a surface of the source region to a portion deeper than the base region and extends longitudinally in one direction and has a Si-face bottom. The trench has an inverse tapered shape, which has a smaller width at an entrance portion than at a bottom, at least at a portion that is in contact with the base region.

Abstract: A nonvolatile memory device includes a first channel comprising a pair of first pillars vertically extending from a substrate and a first coupling portion positioned under the pair of first pillars and coupling the pair of first pillars, a second channel adjacent to the first channel comprising a pair of second pillars vertically extending from the substrate and a second coupling portion positioned under the pair of second pillars and coupling the pair of second pillars, a plurality of gate electrode layers and interlayer dielectric layers alternately stacked along the first and second pillar portions, and first and second trenches isolating the plurality of gate electrode layers between the pair of first pillar portions and between the pair of second pillar portions, respectively.

Abstract: A method of manufacturing a tunnel field effect transistor (TFET) includes forming on a substrate covered by an epitaxially grown source material a dummy gate stack surrounded by sidewall spacers; forming doped source and drain regions followed by forming an inter-layer dielectric surrounding the sidewall spacers; removing the dummy gate stack, etching a self-aligned cavity; epitaxially growing a thin channel region within the self-aligned etch cavity; conformally depositing gate dielectric and metal gate materials within the self-aligned etch cavity; and planarizing the top surface of the replacement metal gate stack to remove the residues of the gate dielectric and metal gate materials.

Abstract: In a vertical MOS transistor in which a semiconductor pillar is formed by etching a semiconductor substrate in a portion surrounded by an isolation film, the semiconductor pillar is covered with a gate insulating film and a gate electrode to be made a channel part, and diffusion layers to be a source and a drain are included on a top and a bottom of the channel part, electrode which controls potential of a gate electrode material is formed in gate electrode material formed on a side surface of isolation film, in order to eliminate a parasitic MOS operation by the gate electrode material remaining on the side surface of the isolation film.

Abstract: A vertical transistor includes a semiconductor substrate provided with a pillar type active pattern over the surface thereof. A first tensile layer is formed over the semiconductor substrate and around the lower end portion of the pillar type active pattern, and a second tensile layer is formed over the upper end portion of the pillar type active pattern so that a tensile stress is applied in a vertical direction to the pillar type active pattern. A first junction region is formed within the surface of the semiconductor substrate below the first tensile layer and the pillar type active pattern. A gate is formed so as to surround at least a portion of the pillar type active pattern. A second junction region is formed within the upper end portion of the pillar type active pattern.

Abstract: According to one embodiment, a semiconductor device includes a first semiconductor region; a second semiconductor region having a side face and a lower face, and the faces surrounded by the first semiconductor region; a third semiconductor region provided between the second semiconductor region and the first semiconductor region; a fourth semiconductor region being in contact with an outer side face of the first semiconductor region; a plurality of first electrodes being in contact with the second semiconductor region, the third semiconductor region, and the first semiconductor region via an insulating film; a plurality of pillar areas extending from the third semiconductor region toward the fourth semiconductor region, each of the plurality of pillar areas being provided between adjacent ones of the plurality of first electrodes. An impurity density of each of the pillar areas and an impurity density of the third semiconductor region is substantially the same.

Abstract: A Semiconductor device includes a substrate having an active region defined by a device isolation layer, a trench formed by etching the active region and the device isolation layer, a buried gate filling a portion of the trench, an interlayer insulation layer formed over the buried gate and filling a remainder of the trench, and an oxidation protecting layer formed between the buried gate and the device isolation layer.

Abstract: Embodiments of the invention relate to field effect transistors. The field effect transistor includes a gate electrode for providing a gate field, a first electrode including a conductive material having a low carrier density and a low density of electronic states, a second electrode, and a semiconductor. Contact barrier modulation includes barrier height lowering of a Schottky contact between the first electrode and the semiconductor. In some embodiments of the invention, a vertical field effect transistor employs an electrode comprising a conductive material with a low density of states such that the transistors contact barrier modulation comprises barrier height lowering of the Schottky contact between the electrode with a low density of states and the adjacent semiconductor by a Fermi level shift.

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

Abstract: The present disclosure relates to a device and method for strain inducing or high mobility channel replacement in a semiconductor device. The semiconductor device is configured to control current from a source to a drain through a channel region by use of a gate. A strain inducing or high mobility layer produced in the channel region between the source and drain can result in better device performance compared to Si, faster devices, faster data transmission, and is fully compatible with the current semiconductor manufacturing infrastructure.

Abstract: In a semiconductor die, source zones of a first conductivity type and body zones of a second conductivity type are formed. Both the source and the body zones adjoin a first surface of the semiconductor die in first sections. An impurity source is provided in contact with the first sections of the first surface. The impurity source is tempered so that atoms of a metallic recombination element diffuse out from the impurity source into the semiconductor die. Then impurities of the second conductivity type are introduced into the semiconductor die to form body contact zones between two neighboring source zones, respectively. The atoms of the metallic recombination element reduce the reverse recovery charge in the semiconductor die. Providing the body contact zones after tempering the platinum source provides uniform and reliable body contacts.

Abstract: The present invention relates to providing layers of different thickness on vertical and horizontal surfaces (15, 20) of a vertical semiconductor device (1). In particular the invention relates to gate electrodes and the formation of precision layers (28) in semiconductor structures comprising a substrate (10) and an elongated structure (5) essentially standing up from the substrate. According to the method of the invention the vertical geometry of the device (1) is utilized in combination with either anisotropic desposition or anisotropic removal of deposited material to form vertical or horizontal layers of very high precision.

Abstract: A power semiconductor device according to the present invention, which has a termination structure in which a field plate is provided on an insulating film filled in a recessed region formed in a semiconductor substrate and includes a plurality of unit cells connected in parallel, includes: a gate wiring region in which gate wiring electrically connected to each gate electrode of the plurality of unit cells is provided; and a gate pad region electrically connected to the gate wiring region, wherein the gate wiring region is disposed on the insulating film filled in a recessed region formed in the semiconductor substrate.

Abstract: In one embodiment, a transistor fabricated on a semiconductor die includes a first section of transistor segments disposed in a first area of the semiconductor die, and a second section of transistor segments disposed in a second area of the semiconductor die adjacent the first area. Each of the transistor segments in the first and second sections includes a pillar of a semiconductor material that extends in a vertical direction. First and second dielectric regions are disposed on opposite sides of the pillar. First and second field plates are respectively disposed in the first and second dielectric regions. Outer field plates of transistor segments adjoining first and second sections are either separated or partially merged.

Abstract: An integrated circuit device includes a plurality of pillars protruding from a substrate in a first direction. Each of the pillars includes source/drain regions in opposite ends thereof and a channel region extending between the source/drain regions. A plurality of conductive bit lines extends on the substrate adjacent the pillars in a second direction substantially perpendicular to the first direction. A plurality of conductive shield lines extends on the substrate in the second direction such that each of the shield lines extends between adjacent ones of the bit lines. Related fabrication methods are also discussed.

Abstract: A semiconductor device includes a trench isolation region provided on a substrate and defining first and second active regions separated from each other. A first semiconductor pillar protruding upward from the first active region is provided. A second semiconductor pillar protruding upward from the second active region is provided. A first gate mask extending to cross over the first and second active regions is provided. The first gate mask surrounds upper sidewalls of the first and second semiconductor pillars. A first gate line formed below the first gate mask, separated from the first and second active regions, and surrounding parts of sidewalls of the first and second semiconductor pillars is provided.

Abstract: A fabrication method of a power semiconductor device is provided. Firstly, a plurality of trenched gate structures is formed in the base. Then, a body mask is used for forming a pattern layer on the base. The pattern layer has at least a first open and a second open for forming at least a body region and a heavily doped region in the base respectively. Then, a shielding structure is formed on the base to fill the second open and line at least a sidewall of the first open. Next, a plurality of source doped regions is formed in the body region by using the pattern layer and the shielding structure as the mask. Then, an interlayer dielectric layer is formed on the base and a plurality of source contact windows is formed therein to expose the source doped regions.

Abstract: A method for contacting MOS devices. First openings in a photosensitive material are formed over a substrate having a top dielectric in a first die area and a second opening over a gate stack in a second die area having the top dielectric, a hard mask, and a gate electrode. The top dielectric layer is etched to form a semiconductor contact while etching at least a portion the hard mask layer thickness over a gate contact area exposed by the second opening. An inter-layer dielectric (ILD) is deposited. A photosensitive material is patterned to generate a third opening in the photosensitive material over the semiconductor contact and a fourth opening inside the gate contact area. The ILD is etched through to reopen the semiconductor contact while etching through the ILD and residual hard mask if present to provide a gate contact to the gate electrode.

Abstract: A Vertical Multiple Implanted Silicon Carbide Power MOSFET (VMIMOSFET) includes a first conductivity semiconductor substrate, a first conductivity semiconductor drift layer on the top of the substrate, a multitude of second conductivity layers implanted in the drift layer. The body layer is where the channel is formed. A first conductivity source layer is interspaced appropriately inside of the second conductivity layers. A gate oxide of a certain thickness and another oxide of a different thickness, a greater thickness than the gate oxide, placed in between the body layers but in such way that its shape does not distort the gate oxide in the channel. A charge compensated body layer of the second conductivity formed outside of the channel region and only at specific high electric field locations in the structure. The device and the manufacturing method deliver a power SiC MOSFET with increased frequency of operation and reduced switching losses.

Abstract: A trench MOSFET with shielded electrode and improved avalanche enhancement region is disclosed. The inventive structure can achieve a better avalanche capability by applying an improved avalanche enhancement region having a same doping concentration as the epitaxial layer where said trench MOSFET is formed without increasing Rds.

Abstract: A device includes a semiconductor substrate, and a channel region of a transistor over the semiconductor substrate. The channel region includes a semiconductor material. An air gap is disposed under and aligned to the channel region, with a bottom surface of the channel region exposed to the air gap. Insulation regions are disposed on opposite sides of the air gap, wherein a bottom surface of the channel region is higher than top surfaces of the insulation regions. A gate dielectric of the transistor is disposed on a top surface and sidewalls of the channel region. A gate electrode of the transistor is over the gate dielectric.

Abstract: Disclosed herein are various methods of forming replacement gate structures with a recessed channel region. In one example, the method includes forming a sacrificial gate structure above a semiconducting substrate, removing the sacrificial gate structure to thereby define an initial gate opening having sidewalls and to expose a surface of the substrate and performing an etching process on the exposed surface of the substrate to define a recessed channel in the substrate. The method includes the additional steps of forming a sidewall spacer within the initial gate opening on the sidewalls of the initial gate opening to thereby define a final gate opening and forming a replacement gate structure in the final gate opening.

Abstract: A field-effect semiconductor device is provided. The field-effect semiconductor device includes a semiconductor body with a first surface defining a vertical direction. In a vertical cross-section the field-effect semiconductor device further includes a vertical trench extending from the first surface into the semiconductor body. The vertical trench includes a field electrode, a cavity at least partly surrounded by the field electrode, and an insulation structure substantially surrounding at least the field electrode. Further, a method for producing a field-effect semiconductor device is provided.

Abstract: According to one embodiment, a semiconductor device includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type which is provided on the first semiconductor layer, a third semiconductor layer of the first conductivity type which is selectively provided on a surface of the second semiconductor layer, an insulating film which is provided to cover an inner wall of a trench running into the first semiconductor layer from an upper face of the third semiconductor layer, a field plate electrode which is provided in a lower portion of the trench, a gate electrode which is provided on the field plate electrode via the insulating film, and a fourth semiconductor layer of the second conductivity type which is provided at least in a region direct below the trench, and comes into contact with the insulating film.

Abstract: An electronic device can include a transistor structure, including a patterned semiconductor layer overlying a substrate, wherein the patterned semiconductor layer defines first and second trenches. The electronic device can also include a first conductive structure within the first trench, a gate electrode within the first trench and overlying the first conductive structure, a first insulating member within the second trench, and a second conductive structure within the second trench. The second conductive structure can include a first portion and a second portion overlying the first portion, the first insulating member can be disposed between the patterned semiconductor layer and the first portion of the second conductive structure; and the second portion of the second conductive structure can contact the patterned semiconductor layer at a Schottky region. Processes of forming the electronic device can take advantage of integrating formation of the Schottky region into a contact process flow.

Abstract: A power semiconductor device includes a first semiconductor layer of a first conductivity type, a second semiconductor layer of a second conductivity type, a third semiconductor layer of the first conductivity type, a fourth semiconductor layer of the second conductivity type. The first semiconductor layer has a first surface and a second surface on opposite side from the first surface and includes a first trench extending from the first surface. The gate electrode is provided via a gate insulating film on the first semiconductor layer, on the second semiconductor layer, and on the third semiconductor layer in the first trench. The fourth semiconductor layer is extending from the first surface of the first semiconductor layer to the second surface side farther than the first trench. A conductor is provided via an insulating film in the fourth semiconductor layer. The conductor is electrically connected to the gate electrode.

Abstract: A power MOSFET includes an epitaxy substrate, conductive trenches, well regions and a dielectric layer. The power MOSFET further has at least one termination structure including at lest one of the conductive trenches, some of the well regions within a termination area and mutually insulated by the conductive trench, a field plate, a contact plug and a heavily-doped region. The field plate including a plate metal and the dielectric layer is on the well regions and the conductive trench within the termination area. The contact plug penetrates through the dielectric layer and connects the plate metal and one of the well regions, so the plate metal has equal potential with the connected well region through the contact plug. The well regions and the conductive trench are electrically coupled to the plate metal by the dielectric layer. The heavily-doped region is between the contact plug and the connected well region.

Abstract: A memory array structure and a method for forming the same are provided. The memory array structure comprises: a substrate; a plurality of memory cells, each memory cell including a vertical transistor, of which a gate structure is formed in a first trench extending in a first direction; a plurality of word lines in the first direction, each word line formed in the first trench; a plurality of bit lines in a second direction, each bit line formed in lower sides of a semiconductor pillars; a plurality of body lines in the first direction, each body line having a first portion formed on the gate electrodes and a second portion covering a part of a top surface of semiconductor pillar for providing a substrate contact to vertical channel regions; and a plurality of data storage device contacts.

Abstract: Semiconductor memory devices having recessed access devices are disclosed. In some embodiments, a method of forming the recessed access device includes forming a device recess in a substrate material that extends to a first depth in the substrate that includes a gate oxide layer in the recess. The device recess may be extended to a second depth that is greater that the first depth to form an extended portion of the device recess. A field oxide layer may be provided within an interior of the device recess that extends inwardly into the interior of the device recess and into the substrate. Active regions may be formed in the substrate that abut the field oxide layer, and a gate material may be deposited into the device recess.

Abstract: A manufacture includes a doped layer, a body structure over the doped layer, a trench defined in the doped layer, an insulator partially filling the trench, and a first conductive feature buried in, and separated from the doped layer and the body structure by, the insulator. The doped layer has a first type doping. The body structure has an upper surface and includes a body region. The body region has a second type doping different from the first type doping. The trench has a bottom surface. The first conductive feature extends from a position substantially leveled with the upper surface of the body structure toward the bottom surface of the trench. The first conductive feature overlaps the doped layer for an overlapping distance, and the overlapping distance ranging from 0 to 2 ?m.

Abstract: A semiconductor device includes a trench region extending into a drift zone of a semiconductor body from a surface. The semiconductor device further includes a dielectric structure including a first step and a second step along a lateral side of the trench region. The semiconductor device further includes an auxiliary structure of a first conductivity type between the first step and the second step, a gate electrode in the trench region and a body region of a second conductivity type other than the first conductivity type of the drift zone. The auxiliary structure adjoins each one of the drift zone, the body region and the dielectric structure.

Abstract: A semiconductor device includes a trench region extending into a drift zone of a semiconductor body from a surface. The semiconductor device further includes a dielectric structure extending along a lateral side of the trench region, wherein a part of the dielectric structure is a charged insulating structure. The semiconductor device further includes a gate electrode in the trench region and a body region of a conductivity type other than the conductivity type of the drift zone. The charged insulating structure adjoins each one of the drift zone, the body region and the dielectric structure and further adjoins or is arranged below a bottom side of a gate dielectric of the dielectric structure.