Abstract: A semiconductor device according to an embodiment, includes a first dielectric film, a floating gate, a second dielectric film, and a third dielectric film. The first dielectric film is formed above a semiconductor substrate. The floating gate is formed above the first dielectric film by using a silicon film. The third dielectric film is formed to cover an upper surface of the floating gate and a side face portion of the floating gate. The floating gate includes an impurity layer formed on an upper surface of the floating gate and a side face of the floating gate along an interface between the floating gate and the third dielectric film formed to cover the upper surface of the floating gate and a side face portion of the floating gate and containing at least one of carbon (C), nitrogen (N), and fluorine (F) as an impurity.

Abstract: A semiconductor device including a first dielectric film, a floating gate portion, second and third dielectric films, a control gate portion, and a recess on the side face of the floating gate portion. The second dielectric film for element isolation is embedded between a height position of a lower portion of the side face of the floating gate portion and a height position inside the semiconductor substrate. The third dielectric film covers an upper surface and a side face portion of the floating gate portion up to a height position of an upper surface of the second dielectric film, and on the second dielectric film. A height position of an interface between the second and third dielectric films is between a height position of a center of the recess and a position in a predetermined range below the height position of the center of the recess.

Abstract: In accordance with an embodiment, a semiconductor memory device includes a substrate with a semiconductor layer and memory cells on the semiconductor layer. Each memory cell includes a laminated body on the semiconductor layer, a gate insulating film on the laminated body, and a control gate on the gate insulating film. The laminated body includes a tunnel insulating film and a floating gate subsequently laminated in a direction vertical to a front surface of the substrate for N (a natural number equal to or above 2) times. A dimension of a top face of any floating gate in a second or subsequent layer is smaller than a dimension of a bottom surface of the floating gate in the lowermost layer in at least one of a first direction parallel to the front surface of the substrate and a second direction crossing the first direction.

Abstract: A method for enabling fabrication of memory devices requiring no or minimal additional mask for fabrication having a low cost, a small footprint, and multiple-time programming capability is disclosed. Embodiments include: forming a gate stack on a substrate; forming a source extension region in the substrate on one side of the gate stack, wherein no drain extension region is formed on the other side of the gate stack; forming a tunnel oxide liner on side surfaces of the gate stack and on the substrate on each side of the gate stack; forming a charge-trapping spacer on each tunnel oxide liner; and forming a source in the substrate on the one side of the gate stack and a drain in the substrate on the other side of the gate stack.

Abstract: An improved gate structure is provided whereby the gate structure is defined by a trench, the trench having a first oxide layer and a second oxide layer. The invention also provides methods for fabricating the gate structure of the invention defined by a trench having a first oxide layer and a second oxide layer.

Abstract: A device is disclosed. The device includes a substrate and a fin structure disposed on the substrate. The fin structure serves as a common body of n transistors. The transistors include separate charge storage layers and gate dielectric layers. The charge storage layers are disposed over a top surface of the fin structure and the gate dielectric layers are disposed on sidewalls of the fin structure. n=2x, x is a whole number greater or equal to 1. A transistor can interchange between a select transistor and a storage transistor.

Abstract: A three-dimensional (3D) semiconductor memory device may include an electrode structure extending in a first direction and including insulating patterns and horizontal electrodes stacked on a substrate, a semiconductor pillar penetrating the electrode structure and connected to the substrate, a charge storage layer between the semiconductor pillar and the electrode structure, a tunnel insulating layer between the charge storage layer and the semiconductor pillar, and a blocking insulating layer between the charge storage layer and the electrode structure. A first horizontal electrode of the horizontal electrodes includes a gate electrode and a metal stopper between the gate electrode and the blocking insulating layer.

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

Abstract: A semiconductor device includes a trench defined by etching a semiconductor substrate including a device isolation film and an active region, an active region protruded from a side and bottom of the trench, and a gate electrode surrounding the active region simultaneously while being buried in the trench.

Abstract: A semiconductor component arrangement includes a semiconductor body, a transistor structure, a further component, and at least a first electrode structure. The semiconductor body has a first side and a second side. The transistor structure is integrated in the semiconductor body, and includes a source and a drain. The further component is also integrated in the semiconductor body. The first electrode structure is disposed in at least a first trench, and includes at least one electrode. The first electrode structure electrically connects at least one of the source and the drain to the further component.

Abstract: A power semiconductor device with improved avalanche capability is disclosed by forming at least one avalanche capability enhancement doped region underneath an ohmic contact doped region. Moreover, a source mask is saved by using three masks process and the avalanche capability is further improved.

Abstract: A semiconductor device includes a semiconductor pattern on a substrate, gate structures on sidewalls of the semiconductor pattern, the gate structures being spaced apart from one another, insulating interlayers among the gate structures, wherein an uppermost insulating interlayer is lower than an upper face of the semiconductor pattern, a common source line contacting the substrate and protruding above the uppermost insulating interlayer, an etch stop layer pattern on the semiconductor pattern and on the common source line wherein the common source line protrudes above the uppermost insulating interlayer, an additional insulating interlayer on the uppermost insulating interlayer, and contact plugs extending through the additional insulating interlayer so as to make contact with the semiconductor pattern and the common source line, respectively.

Abstract: LDD regions are provided with high implant energy in devices with reduced thickness poly-silicon layers and source/drain junctions. Embodiments include forming an oxide layer on a substrate surface, forming a poly-silicon layer over the oxide layer, forming first and second trenches through the oxide and poly-silicon layers and below the substrate surface, defining a gate region therebetween, implanting a dopant in a LDD region through the first and second trenches, forming spacers on opposite side surfaces of the gate region and extending into the first and second trenches, and implanting a dopant in a source/drain region below each of the first and second trenches.

Abstract: An asymetric gate MOS device is disclosed. The gate is a metal gate, and the metal gate has a different work function on the source side from that on the drain side of the MOS device, so that the overall performance parameters of the MOS device are more optimized. A method of making an asymetric gate MOS device is also disclosed. In the method, dopant ions are implanted into the gate of the MOS device, so as to cause the gate to have a different work function on the source side from that on the drain side of the MOS device. As a result, the overall performance parameters of the MOS device are more optimized. The method can be easily implemented.

Abstract: A semiconductor device includes a high breakdown voltage DMOS transistor formed on a first conductivity type semiconductor substrate. The semiconductor device includes: a DMOS second conductivity type well; a DMOS first conductivity body region; a DMOS second conductivity type source region; a DMOS second conductivity type drain region; a LOCOS oxide film formed between the DMOS second conductivity type drain region and the DMOS first conductivity type body region; and a DMOS gate insulating film formed in succession to the LOCOS oxide film to cover a DMOS channel region between the DMOS second conductivity type source region and the DMOS second conductivity type well, wherein the DMOS gate insulating film includes a first insulating film which is disposed outside the DMOS channel region and a second insulating film which is disposed in the DMOS channel region and is thinner than the first insulating film.

Abstract: A lateral diffusion metal-oxide-semiconductor (LDMOS) transistor structure comprises a barrier layer, a semiconductor layer, a source, a first drain and a guard ring. The barrier layer with a first polarity is disposed in a substrate. The semiconductor layer with a second polarity is disposed on the barrier layer. The source has a first polarity region and a second polarity region both formed in the semiconductor layer. The first drain is disposed in the semiconductor layer and has a drift region with the second polarity. The guard ring with the first polarity extends downward from a surface of the semiconductor layer in a manner of getting in touch with the barrier layer and to surround the source and the drain, and is electrically connected to the source.

Abstract: A semiconductor device includes: a P+ substrate; a P? epitaxial layer over the P+ substrate; a P-well and an N? drift region in the P? epitaxial layer and laterally adjacent to each other; an N+ source region in the P-well and connected to a front-side metal via a first contact electrode; an N+ drain region in the N? drift region and connected to the front-side metal via a second contact electrode; a gate structure on the P? epitaxial layer and connected to the front-side metal via a third contact electrode; and a metal plug through the P? epitaxial layer and having one end in contact with the P+ substrate and the other end connected to the front-side metal, the metal plug being adjacent to one side of the N+ source region that is farther from the N? drift region. A method for fabricating the semiconductor device is also disclosed.

Abstract: An LDMOS device is disclosed. The LDMOS device includes: a substrate having a first type of conductivity; a drift region having a second type of conductivity and a doped region having the first type of conductivity both formed in the substrate; a drain region having the second type of conductivity and being formed in the drift region, the drain region being located at an end of the drift region farther from the doped region; and a buried layer having the first type of conductivity and being formed in the drift region, the buried layer being in close proximity to the drain region and having a step-like bottom surface, and wherein a depth of the buried layer decreases progressively in a direction from the drain region to the doped region. A method of fabricating LDMOS device is also disclosed.

Abstract: A lateral double-diffused metal-oxide-semiconductor (LDMOS) transistor device includes an enhancement implant region formed in a portion of an accumulation region proximate a P-N junction between body and drift drain regions. The enhancement implant region contains additional dopants of the same conductivity type as the drift drain region. There is a gap between the enhancement implant region and the P-N junction. 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: A semiconductor structure including a body-contacted finFET device and methods form manufacturing the same. The method may include forming one or more semiconductor fins on a SOI substrate, forming a semiconductive body contact region connected to the bottom of the fin(s) in the buried insulator region, forming a sacrificial gate structure over the body region of the fin(s), forming a source region on one end of the fin(s), forming a drain region on the opposite end of the fin(s), replacing the sacrificial gate structure with a metal gate, and forming electrical contacts to the source, drain, metal gate, and body contact region. The method may further include forming a body contact fin contemporaneously with the finFET fins that is in contact with the body contact region, through which electrical contact to the body contact region is made.

Abstract: In one aspect, a CMOS device is provided. The CMOS device includes a SOI wafer having a SOI layer over a BOX; one or more active areas formed in the SOI layer in which one or more FET devices are formed, each of the FET devices having an interfacial oxide on the SOI layer and a gate stack on the interfacial oxide layer, the gate stack having (i) a conformal gate dielectric layer present on a top and sides of the gate stack, (ii) a conformal gate metal layer lining the gate dielectric layer, and (iii) a conformal workfunction setting metal layer lining the conformal gate metal layer. A volume of the conformal gate metal layer and/or a volume of the conformal workfunction setting metal layer present in the gate stack are/is proportional to a length of the gate stack.

Abstract: The organic thin-film transistor according to the present invention includes: a gate electrode line on a substrate in a first region: a first signal line layer in a second region; a gate insulating film covering the gate electrode line and the first signal line layer; bank layers on the gate insulating film; a second signal line layer on the bank layer over the first signal line; a drain electrode and a source electrode line which are located on the bank layers and in at least one opening between the bank layers in the first region; a semiconductor layer located at least in the opening and banked up by the bank layers, the drain electrode, and the source electrode line; and a protection film covering the semiconductor layer.

Abstract: After formation of gate stacks, a carbon-based template layer is deposited over the gate stacks, and is optionally planarized to provide a planar top surface. A hard mask layer and a photoresist layer are subsequently formed above the carbon-based template layer. A pattern including openings is formed within the photoresist layer. The pattern is subsequently transferred through the hard mask layer and the carbon-based template layer with high selectivity to gate spacers to form self-aligned cavities within the carbon-based template layer. Contact structures are formed within the carbon-based template layer by a damascene method. The hard mask layer and the carbon-based template layer are subsequently removed selective to the contact structures. The contact structures can be formed as contact bar structures or contact via structures. Optionally, a contact-level dielectric layer can be subsequently deposited.

Abstract: Embodiments of the invention provide dual workfunction semiconductor devices and methods for manufacturing thereof. According to one embodiment, the method includes providing a substrate containing first and second device regions, depositing a dielectric film on the substrate, and forming a first metal-containing gate electrode film on the dielectric film, wherein a thickness of the first metal-containing gate electrode film is less over the first device region than over the second device region. The method further includes depositing a second metal-containing gate electrode film on the first metal-containing gate electrode film, patterning the second metal-containing gate electrode film, the first metal-containing gate electrode film, and the dielectric film to form a first gate stack above the first device region and a second gate stack above the second device region.

Abstract: A method of forming a semiconductor device includes forming a gate stack over a substrate, forming an amorphized region in the substrate adjacent to an edge of the gate stack, forming a stress film over the substrate, performing a process to form a dislocation with a pinchoff point in the substrate, removing at least a portion of the dislocation to form a recess cavity with a tip in the substrate, and forming a source/drain feature in the recess cavity.

Abstract: An integrated circuit having improved radiation immunity is described. The integrated circuit comprises a substrate; an n-well formed on the substrate; a p-well formed on the substrate; and a p-tap formed in the p-well adjacent to the n-well, wherein the p-tap extends between circuit elements formed in the n-well and circuit elements formed in the p-well, and is coupled to a ground potential. A method of forming an integrated circuit having improved radiation immunity is also described.

Abstract: A semiconductor device comprises a substrate comprising a major surface; a p-type Field Effect Transistor (pFET) comprising: a P-gate stack over the major surface, a P-strained region in the substrate adjacent to one side of the P-gate stack, wherein a lattice constant of the P-strained region is different from a lattice constant of the substrate, wherein the P-strained region has a first top surface higher than the major surface; and a P-silicide region on the P-strained region; and an n-type Field Effect Transistor (nFET) comprising: an N-gate stack over the major surface, an N-strained region in the substrate adjacent to one side of the N-gate stack, wherein a lattice constant of the N-strained region is different from a lattice constant of the substrate, wherein the N-strained region has a second top surface lower than the major surface and a N-silicide region on the N-strained region.

Abstract: An integrated circuit is disclosed that has substantially continuous active diffusion regions within its diffusion layers. Active regions of semiconductor devices can be fabricated using portions of these substantially continuous active diffusion regions. Stress can be applied to these semiconductor devices during their fabrication which leads to substantially uniform stress patterns throughout the integrated circuit. The substantially uniform stress patterns can significantly improve performance of the integrated circuit.

Abstract: A semiconductor memory device and a method of manufacturing the same are provided. The device includes a semiconductor substrate in which active regions and isolation regions are alternately defined, and a support region is defined in a direction crossing the active regions and the isolation regions, first trenches formed in the isolation regions, second trenches formed under the first trenches in the active regions and the isolation regions; and a support layer formed under the first trenches in the support region.

Abstract: A method is provided for fabricating a PMOS transistor. The method includes providing a semiconductor substrate, and forming a dummy gate structure at least having a dummy gate, a high-K dielectric layer, and a sidewall spacer surrounding the high-K dielectric layer and the dummy gate on the semiconductor substrate. The method also includes forming a source region and a drain region in the semiconductor substrate at both sides of the dummy gate structure by an ion implantation process, and performing a first annealing process to enhance the ion diffusion. Further, the method includes forming an interlayer dielectric layer leveling with the surface of the dummy gate, and forming a trench by removing the dummy gate. Further, the method also includes performing a second annealing process, and forming a metal gate in the trench.

Abstract: An integrated circuit structure has a substrate comprising a well region and a surface region, an isolation region within the well region, a gate insulating layer overlying the surface region, first and second source/drain regions within the well region of the substrate. The structure also has a channel region formed between the first and second source/drain regions and within a vicinity of the gate insulating layer, and a gate layer overlying the gate insulating layer and coupled to the channel region. The structure has sidewall spacers on edges of the gate layer to isolate the gate layer, a local interconnect layer overlying the surface region of the substrate and having an edge region extending within a vicinity of the first source/drain region. A contact layer on the first source/drain region in contact with the edge region and has a portion abutting a portion of the sidewall spacers.

Abstract: The present disclosure provides a semiconductor memory device. The device includes a pinning layer having an anti-ferromagnetic material and disposed over a first electrode; a pinned layer disposed over the pinning layer; a tunneling layer disposed over the pinned layer, a free layer disposed over the tunneling layer and a capping layer disposed over the free layer. The capping layer includes metal-oxide and metal-nitride materials.

Abstract: Systems and methods for multiple-time programmable (MTP) devices. An MTP device includes a magnetic tunnel junction (MTJ) device programmable to a plurality of states based on voltage applied across the MTJ device. The plurality of states include a first resistance state corresponding to a first binary value stored in the MTJ device based on a first voltage, a second resistance state corresponding to a second binary value stored in the MTJ device based on a second voltage, a third resistance state corresponding to a breakdown of a barrier layer of the MTJ device based on a third voltage, and a fourth resistance state corresponding to an open fuse based on a fourth voltage.

Abstract: A magnetic tunnel junction (MTJ) device includes a reference layer having a surface, a tunnel insulating layer formed over the surface of the reference layer, and a free layer formed over the tunnel insulating layer. A magnetization direction in each of the reference layer and the free layer is substantially perpendicular to the surface. A dimension of the reference layer in a horizontal direction substantially parallel to the surface is larger than a dimension of the free layer in the horizontal direction.

Abstract: A magnetic tunnel junction (MTJ) device includes a reference layer having a surface, a tunnel insulating layer formed over the surface of the reference layer, a free layer formed over the tunnel insulating layer, and a magnetic field providing layer formed over the free layer. A magnetization direction in each of the reference layer and the free layer is substantially perpendicular to the surface. The magnetic field providing layer is configured to provide a lateral magnetic field in the free layer, the lateral magnetic field being substantially parallel to the surface.

Abstract: Embodiments of a pixel including a substrate having a front surface and a photosensitive region formed in or near the front surface of the substrate. An isolation trench is formed in the front surface of the substrate adjacent to the photosensitive region. The isolation trench includes a trench having a bottom and sidewalls, a passivation layer formed on the bottom and the sidewalls, and a filler to fill the portion of the trench not filled by the passivation layer.

Abstract: A backside illuminated (BSI) CMOS image sensor is disclosed. The BSI CMOS image sensor includes: a substrate having a front side and a back side, the substrate including a photodiode formed therein, the photodiode being proximate the back side of the substrate; a metal shielding layer covering the back side of the substrate, the metal shielding layer including an opening formed therein, the opening being arranged in correspondence with the photodiode; and a light-absorbing layer formed on each side face of the opening. The light-absorbing layer coated on the side faces of the opening prevents the occurrence of photon cross-talk and hence improves imaging quality of the BSI CMOS image sensor.

Abstract: Methods for laser processing semiconductor materials for use in optoelectronic and other devices, including materials, devices, and systems associated therewith are provided. In one aspect, a method of minimizing laser-induced material damage while laser-texturing a semiconductor material can include delivering short pulse duration laser radiation to a target region of a semiconductor material to form a textured region having a reorganized surface layer, wherein the laser radiation has a wavelength from about 200 nm to about 600 nm and a pulse duration of from about 10 femtoseconds to about 400 picoseconds, and wherein defect density of the semiconductor material from beneath the reorganized surface layer up to a depth of about 1 micron is less than or equal to about 1012/cm3.

Abstract: An integrated circuit (IC) comprises a plurality of photovoltaic (PV) cells formed over a passivation layer of a target integrated circuit (TIC), wherein at least one PV cell of the plurality of PV cells is usable as a light sensing device; an interface to an energy storage unit; the TIC comprising at least: a control unit; and a switching circuit, the switching circuit coupled to the plurality of PV cells, the energy storage, and the control unit; wherein the control unit is configured to control at least the switching circuit to configure a connection scheme, wherein the connection scheme devises at least one first PV cell of the plurality of PV cells to connect to the energy storage and at least one second PV cell to connect to the control unit for light detection.

Abstract: In a rectifier device (2) for full-wave rectifying an output of a vehicle alternating-current generator (1), a schottky barrier diode having a characteristic whose forward voltage drop with respect to a forward current is small and whose reverse leakage current is small, is used as a rectifier semiconductor element (201),(202) constituting the rectifier device (2).

Abstract: An MPS diode includes a III-nitride substrate characterized by a first conductivity type and a first dopant concentration and having a first side and a second side. The MPS diode also includes a III-nitride epitaxial structure comprising a first III-nitride epitaxial layer coupled to the first side of the substrate, wherein a region of the first III-nitride epitaxial layer comprises an array of protrusions. The III-nitride epitaxial structure also includes a plurality of III-nitride regions of a second conductivity type, each partially disposed between adjacent protrusions. Each of the plurality of III-nitride regions of the second conductivity type comprises a first section laterally positioned between adjacent protrusions and a second section extending in a direction normal to the first side of the substrate. The MPS diode further includes a first metallic structure electrically coupled to one or more of the protrusions and to one or more of the second sections.

Abstract: A method for fabricating edge termination structures in gallium nitride (GaN) materials includes providing an n-type GaN substrate having a first surface and a second surface, forming an n-type GaN epitaxial layer coupled to the first surface of the n-type GaN substrate, and forming one or more p-type regions in the n-type GaN epitaxial layer by using a first ion implantation. At least one of the one or more p-type regions includes an edge termination structure.

Abstract: One embodiment of a semiconductor device includes a semiconductor body with a first side and a second side opposite to the first side. The semiconductor device further includes a first contact trench extending into the semiconductor body at the first side. The first contact trench includes a first conductive material electrically coupled to the semiconductor body adjoining the first contact trench. The semiconductor further includes a second contact trench extending into the semiconductor body at the second side. The second contact trench includes a second conductive material electrically coupled to the semiconductor body adjoining the second contact trench.

Abstract: An anti-fuse structure is provided in which an anti-fuse material liner is embedded within one of the openings provided within an interconnect dielectric material. The anti-fuse material liner is located between a first conductive metal and a second conductive metal which are also present within the opening. A diffusion barrier liner separates the first conductive metal from any portion of the interconnect dielectric material. The anti-fuse structure is laterally adjacent an interconnect structure that is formed within the same interconnect dielectric material as the anti-fuse structure.

Abstract: A semiconductor device has a semiconductor package and an interposer disposed over the semiconductor package. The semiconductor package has a first semiconductor die and a modular interconnect unit disposed in a peripheral region around the first semiconductor die. A second semiconductor die is disposed over the interposer opposite the semiconductor package. An interconnect structure is formed between the interposer and the modular interconnect unit. The interconnect structure is a conductive pillar or stud bump. The modular interconnect unit has a core substrate and a plurality of vertical interconnects formed through the core substrate. A build-up interconnect structure is formed over the first semiconductor die and modular interconnect unit. The vertical interconnects of the modular interconnect unit are exposed by laser direct ablation. An underfill is deposited between the interposer and semiconductor package.

Abstract: A semiconductor device including power TSVs for stably supplying a power source is described. A semiconductor device includes a chip power pad placed in a first region of a chip, power through silicon vias (TSVs) connected to the chip power pad and placed in the second region of each of the chips, and metal lines configured to couple the chip power pad and the power TSVs.

Abstract: A semiconductor substrate assembly is proposed. The semiconductor interposer comprises a substrate having a first surface and a second surface opposite to the first surface, a first conductive pad, a second conductive pad and a conductive pillar. The first conductive pad is formed at a predetermined location of the first surface of the substrate. The second conductive pad is formed at a predetermined location of the second surface of the substrate as compared with the position of the first conductive pad. The conductive pillar is formed in the substrate and contacts with one of the first conductive pad and the second conductive pad.

Abstract: A compliant bipolar micro device transfer head array and method of forming a compliant bipolar micro device transfer array from an SOI substrate are described. In an embodiment, a compliant bipolar micro device transfer head array includes a base substrate and a patterned silicon layer over the base substrate. The patterned silicon layer may include first and second silicon interconnects, and first and second arrays of silicon electrodes electrically connected with the first and second silicon interconnects and deflectable into one or more cavities between the base substrate and the silicon electrodes.

Abstract: Provided is a substrate structure, including: a first substrate and a second substrate arranged correspondingly. A first surface of the first substrate faces a second surface of the second substrate, wherein the first surface is successively arranged with a conductor interconnection layer and a bonding layer, with the bonding layer connecting the first substrate and the conductor interconnection layer to the second substrate. The substrate structure and a method for manufacturing the same. The second substrate can serve as a support substrate and the first substrate as a substrate for directly manufacturing a device. However, the first substrate is formed by the growth of a crystal without the problem of thickness and stress thereof, thereby avoiding unnecessary stress and further improving the performance of the device formed in the first substrate.

Abstract: A lateral semiconductor device includes a semiconductor layer, an insulating layer, and a resistive field plate. The semiconductor layer includes a first semiconductor region and a second semiconductor region at a surface portion, and the second semiconductor region makes a circuit around the first semiconductor region. The insulating layer is formed on a surface of the semiconductor layer and is disposed between the first and second semiconductor regions. The resistive field plate is formed on a surface of the insulating layer. Between the first and second semiconductor regions, a first section and a second section are adjacent to each other along a circumferential direction around the first semiconductor region. The resistive field plate includes first and second resistive field plate sections respectively formed in the first and second sections, and the first and second resistive field plate sections are separated from each other.