Abstract: A process of producing a diamond thin-film includes implanting dopant into a diamond by an ion implantation technique, forming a protective layer on at least part of the surface of the ion-implanted diamond, and firing the protected ion-implanted diamond at a firing pressure of no less than 3.5 GPa and a firing temperature of no less than 600° C. A process of producing a diamond semiconductor includes implanting dopant into each of two diamonds by an ion implantation technique and superimposing the two ion-implanted diamonds on each other such that at least part of the surfaces of each of the ion-implanted diamonds makes contact with each other, and firing the ion implanted diamonds at a firing pressure of no less than 3.5 GPa and a firing temperature of no less than 600° C.

Abstract: A lateral overflow drain and a channel stop are fabricated using a double mask process. Each lateral overflow drain is formed within a respective channel stop. Due to the use of two mask layers, one edge of each lateral overflow drain is aligned, or substantially aligned, with an edge of a respective channel stop.

Abstract: A semiconductor device is formed in a thin float zone wafer. Junctions are diffused into the top surface of the wafer and the wafer is then reduced in thickness by removal of material from its bottom surface. A weak collector is then formed in the bottom surface by diffusion of boron (for a P type collector). The weak collector is then formed or activated only over spaced or intermittent areas. This is done by implant of the collector impurity through a screening mask; or by activating only intermittent areas by a laser beam anneal in which the beam is directed to anneal only preselected areas. The resulting device has an effective very low implant dose, producing a reduced switching energy and increased switching speed, as compared to prior art weak collector/anodes and life time killing technologies.

Abstract: A method is provided to fabricate a semiconductor device, where the method includes providing a substrate comprised of crystalline silicon; implanting a ground plane in the crystalline silicon so as to be adjacent to a surface of the substrate, the ground plane being implanted to exhibit a desired super-steep retrograde well (SSRW) implant doping profile; annealing implant damage using a substantially diffusionless thermal annealing to maintain the desired super-steep retrograde well implant doping profile in the crystalline silicon and, prior to performing a shallow trench isolation process, depositing a silicon cap layer over the surface of the substrate. The substrate may be a bulk Si substrate or a Si-on-insulator substrate. The method accommodates the use of an oxynitride gate stack structure or a high dielectric constant oxide/metal (high-K/metal) gate stack structure.

Abstract: Various aspects of the technology are directed to integrated circuit manufacturing methods and integrated circuits. In one method, a first charge type buried layer in a semiconductor material of an integrated circuit by implanting first charge type dopants of the first charge type buried layer through a sacrificial oxide over the semiconductor material and through an intermediate region of the semiconductor material transited by the implanted first charge type dopants. When the implanted dopants pass through the sacrificial oxide, damage to the semiconductor crystalline lattice is averted. If the sacrificial oxide were absent, the implanted dopants would have passed through and damaged the semiconductor crystalline lattice instead. Later, a pre-anneal oxide is grown and removed.

Abstract: This method for manufacturing a SIMOX wafer includes: forming a mask layer on one surface side of a silicon single crystal wafer, which has an opening on a region where a BOX layer is to be formed; implanting oxygen ions through the opening of the mask layer into the silicon single crystal wafer to a predetermined depth, and locally forming an oxygen implantation region; annealing the silicon single crystal wafer with the mask layer, and oxidizing the oxygen implantation region so as to form the BOX layer; and removing a coated oxide film that covers the whole silicon single crystal wafer which is formed in the annealing of the silicon single crystal wafer, wherein the mask layer has a lamination comprising an oxide film and either one or both of a polysilicon film and an amorphous silicon film.

Abstract: To prevent bubbles from occurring along a transfer interface, the present method includes the steps of: forming a peeled layer 10 in a transferred member 6 by implanting a peeled-layer forming substance into the transferred member 6; forming a planar surface in the transferred member 6 by planarizing a surface of the transferred member 6; forming a composite including the transferred member 6 and a glass substrate 2 by directly combining the transferred member 6 via the planar surface with a surface of the glass substrate 2; and peeling a part of the transferred member 6 from the composite along the peeled layer 10 serving as an interface by heat-treating the composite.

Abstract: An electronic device includes a drift layer having a first conductivity type, a buffer layer having a second conductivity type, opposite the first conductivity type, on the drift layer and forming a P-N junction with the drift layer, and a junction termination extension region having the second conductivity type in the drift layer adjacent the P-N junction. The buffer layer includes a step portion that extends over a buried portion of the junction termination extension. Related methods are also disclosed.

Abstract: A method for producing a buried stop zone in a semiconductor body and a semiconductor component having a stop zone, the method including providing a semiconductor body having a first and a second side and a basic doping of a first conduction type. The method further includes irradiating the semiconductor body via one of the sides with protons, as a result of which protons are introduced into a first region of the semiconductor body situated at a distance from the irradiation side. The method also includes carrying out a thermal process in which the semiconductor body is heated to a predetermined temperature for a predetermined time duration, the temperature and the duration being chosen such that hydrogen-induced donors are generated both in the first region and in a second region adjacent to the first region in the direction of the irradiation side.

Abstract: A complementary metal-oxide semiconductor (CMOS) image sensor includes a photodiode formed in a substrate structure, first to fourth gate electrodes formed over the substrate structure, spacers formed on both sidewalls of the first to fourth gate electrodes and filled between the third and fourth gate electrodes, a first ion implantation region formed in a portion of the substrate structure below the spacers filled between the third and fourth gate electrodes, and second ion implantation regions formed in portions of the substrate structure exposed between the spacers, the second ion implantation regions having a higher concentration than the first ion implantation region.

Abstract: A semiconductor device receiving as input a radio frequency signal having a frequency of 500 MHz or more and a power of 20 dBm or more is provided. The semiconductor device includes: a silicon substrate; a silicon oxide film formed on the silicon substrate; a radio frequency interconnect provided on the silicon oxide film and passing the radio frequency signal; a fixed potential interconnect provided on the silicon oxide film and placed at a fixed potential; and an acceptor-doped layer. The acceptor-doped layer is formed in a region of the silicon substrate. The region is in contact with the silicon oxide film. The acceptor-doped layer is doped with acceptors.

Abstract: A method for manufacturing a semiconductor device including a vertical double-diffusedmetal-oxide-semiconductor (VDMOS) transistor includes preparing a semiconductor substrate and injecting a first impurity of a second conductivity type to a first region, injecting a second impurity to a second region that is located inside and is narrower than the first region, and forming an epitaxial layer on the semiconductor substrate and forming the semiconductor layer constituted by the semiconductor substrate and the epitaxial layer, and at a same time, diffusing the first and the second impurities injected in a first impurity injection and a second impurity injection to form a buried layer of the second conductivity type.

Abstract: An integrated circuit device with a semiconductor body and a method for the production of a semiconductor device a provided. The semiconductor body comprises a cell field with a drift zone of a first conduction type. In addition, the semiconductor device comprises an edge region surrounding the cell field. Field plates with a trench gate structure are arranged in the cell field, and an edge trench surrounding the cell field is provided in the edge region. The front side of the semiconductor body is in the edge region provided with an edge zone of a conduction type complementing the first conduction type with doping materials of body zones of the cell field. The edge zone of the complementary conduction type extends both within and outside the edge trench.

Abstract: A method for semiconductor processing provides a DSB semiconductor body having a first crystal orientation, a second crystal orientation, and a border region disposed between the first and second crystal orientations. The border region further has a defect associated with an interface of the first crystal orientation and second the second crystal orientation, wherein the defect generally extends a distance into the semiconductor body from a surface of the body. A sacrificial portion of the semiconductor body is removed from the surface thereof, wherein removing the sacrificial portion at least partially removes the defect. The sacrificial portion can be defined by oxidizing the surface at low temperature, wherein the oxidation at least partially consumes the defect. The sacrificial portion can also be removed by CMP. An STI feature may be further formed over the defect after removal of the sacrificial portion, therein consuming any remaining defect.

Abstract: In a semiconductor device using a SiC substrate, a Junction Termination Edge (JTE) layer is hardly affected by fixed charge so that a stable dielectric strength is obtained. A semiconductor device according to a first aspect of the present invention includes a SiC epi-layer having n type conductivity, an impurity region in a surface of the SiC epi-layer and having p type conductivity, and JTE layers adjacent to the impurity region, having p type conductivity, and having a lower impurity concentration than the impurity region. The JTE layers are spaced by a distance from an upper surface of the SiC epi-layer, and SiC regions having n type conductivity are present on the JTE layers.

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of introducing energetic particles (22) through a surface of a donor substrate (10) to a selected depth (20) underneath the surface, where the particles have a relatively high concentration to define a donor substrate material (12) above the selected depth. An energy source is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A semiconductor 100 has a P? body region and an N? drift region in the order from an upper surface side thereof. A gate trench and a terminal trench passing through the P? body region are formed. The respective trenches are surrounded with P diffusion regions at the bottom thereof. The gate trench builds a gate electrode therein. A P?? diffusion region, which is in contact with the end portion in a lengthwise direction of the gate trench and is lower in concentration than the P? body region and the P diffusion region, is formed. The P?? diffusion region is depleted prior to the P diffusion region when the gate voltage is off. The P?? diffusion region serves as a hole supply path to the P diffusion region when the gate voltage is on.

Abstract: A semiconductor device including at least one drift region formed near a channel region on a substrate, a first buried insulating layer formed in the drift region, and a first reduced surface field region interposed between the first buried insulating layer and the drift region. Accordingly, the semiconductor device provides first reduced surface field regions arranged between drift regions and first buried insulating layers, thus having advantages of improved junction integrity, suitability for LDMOS transistors employing a high operation voltage and reduced total size.

Abstract: A semiconductor device including at least one capacitor formed in wiring levels on a silicon-on-insulator (SOI) substrate, wherein the at least one capacitor is coupled to an active layer of the SOI substrate. A method of fabricating a semiconductor structure includes forming an SOI substrate, forming a BOX layer over the SOI substrate, and forming at least one capacitor in wiring levels on the BOX layer, wherein the at least one capacitor is coupled to an active layer of the SOI substrate.

Abstract: In the substrate and the epitaxial layer, isolation regions are formed to divide the substrate and the epitaxial layer into a plurality of element formation regions. Each of the isolation regions is formed by connecting first and second P type buried diffusion layers with a P type diffusion layer. By disposing the second P type buried diffusion layer between the first P type buried diffusion layer and the P type diffusion layer, a lateral diffusion width of the first P type buried diffusion layer is reduced. This structure allows a formation region of the isolation region to be reduced in size.

Abstract: Devices comprising, and a method for fabricating, a remote doped high performance transistor having improved subthreshold characteristics are disclosed. In one embodiment a field-effect transistor includes a channel layer configured to convey between from a source portion and a drain portion of the transistor when the transistor is in an active state. Further, the field-effect transistor includes a barrier layer adjacent to the channel layer. The barrier layer comprises a delta doped layer configured to provide carriers to the channel layer of the transistor, while preferably substantially retaining dopants in said delta-doped layer.

Abstract: A semiconductor structure consistent with certain implementations has a crystalline substrate oriented with a {111} plane surface that is within 10 degrees of surface normal. An epitaxially grown electrically insulating interlayer overlays the crystalline substrate and establishes a coincident lattice that mates with the surface symmetry of the {111} plane surface. An atomically stable two dimensional crystalline film resides on the epitaxial insulating layer with a coincident lattice match to the insulating interlayer. Methods of fabrication are disclosed. This abstract is not to be considered limiting, since other embodiments may deviate from the features described in this abstract.

Abstract: There is provided a method for suppressing the occurrence of defects such as voids or blisters even in the laminated wafer having an oxide film of a thickness thinner than the conventional one, wherein hydrogen ions are implanted into a wafer for active layer having an oxide film of not more than 50 nm in thickness to form a hydrogen ion implanted layer, and ions other than hydrogen are implanted up to a position that a depth from the surface side the hydrogen ion implantation is shallower than the hydrogen ion implanted layer, and the wafer for active layer is laminated onto a wafer for support substrate through the oxide film, and then the wafer for active layer is exfoliated at the hydrogen ion implanted layer.

Abstract: A substrate surface serving as an SOI region and a substrate surface serving as a bulk region are made to form the same plane easily and highly accurately, a thickness of a buried oxide film is made uniform, and the buried oxide film is also prevented from being exposed on the substrate surface. After partially forming a mask oxide film (19) on a surface of a silicon substrate (12), an oxygen ions (16) are implanted into the surface of the substrate through this mask oxide film, and the substrate is further subjected to annealing treatment to form a buried oxide film (13) inside the substrate. Between the step of forming the mask oxide film and the step of implanting the oxygen ions, a recess portion (12c) with a predetermined depth deeper than a substrate surface (12b) serving as the bulk region where the mask oxide film has been formed is formed in a substrate surface (12a) serving as the SOI region where the mask oxide film is not formed.

Abstract: CMOS image sensors and methods of fabricating the same. The CMOS image sensors include a pixel array region having an active pixel portion and an optical block pixel portion which encloses the active pixel portion. The optical block pixel portion includes an optical block metal pattern for blocking light. The optical block metal pattern may be connected to a ground portion.

Abstract: The invention concerns a method of treating one or both bonding surfaces of first and second substrates and in particular, the surfaces of donor and receiver wafers that are intended to be bonded together. A simultaneous cleaning and activation step is carried out immediately prior to bonding the wafers together, by applying to one or both bonding surfaces an activation solution of ammonia (NH4OH) in water, preferably deionized, at a concentration by weight in the range from about 0.05% to 2%. The method is applicable to fabricating structures used in the optics, electronics, or optoelectronics fields.

Abstract: A semiconductor body includes a substrate, a buried zone having a first conductivity type that is formed in the substrate, a first zone having the first conductivity type that is above the buried zone, a second zone having a second conductivity type that is different from the first conductivity type and above the first zone, and a third zone having the first conductivity type that is above the second zone. The buried zone includes first and second implantation regions that are formed via first and second implantations that are performed using a mask. The buried zone, the first zone, the second zone and the third zone are parts of a first transistor structure.

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of introducing energetic particles (22) through a surface of a donor substrate (10) to a selected depth (20) underneath the surface, where the particles have a relatively high concentration to define a donor substrate material (12) above the selected depth. An energy source is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A semiconductor structure including a trench formed in a substrate and a buried isolation collar that extends about sidewalls of the trench. The buried isolation collar is constituted by an insulator formed from a buried porous region of substrate material. The porous region is formed from a buried doped region defined using masking and ion implantation or by masking the trench sidewalls and using dopant diffusion. Advantageously, the porous region is transformed to an oxide insulator by an oxidation process. The semiconductor structure may be a storage capacitor of a memory cell further having a buried plate about the trench and a capacitor node inside the trench that is separated from the buried plate by a node dielectric formed on the trench sidewalls.

Abstract: To easily and accurately flush a substrate surface serving an SOI area with a substrate surface serving as a bulk area, make a buried oxide film, and prevent an oxide film from being exposed on substrate surface. After partially forming a mask oxide film 23 on the surface of a substrate 12 constituted of single crystal silicon, oxygen ions 16 are implanted into the surface of the substrate through the mask oxide film, and the substrate is annealed to form an buried oxide film 13 inside the substrate. Further included is a step of forming a predetermined-depth concave portion 12c deeper than substrate surface 12b serving as a bulk area on which the mask oxide film is formed on the substrate surface 12a serving as an SOI area by forming a thermally grown oxide film 21 on the substrate surface 12a serving as an SOI area on which the mask oxide film is not formed between the step of forming the mask oxide film and the step of implanting oxygen ions.

Abstract: A SIMOX wafer having a BOX layer with a thin film thickness is obtained without a reduction in productivity or deterioration in quality. In a method for manufacturing a SIMOX wafer comprising: a step of forming a first ion-implanted layer in a silicon wafer; a step of forming a second ion-implanted layer that is in an amorphous state; and a high-temperature heat treatment step of maintaining the wafer in an oxygen contained atmosphere at a temperature that is not lower than 1300° C. but less than a silicon melting point for 6 to 36 hours to change the first and the second ion-implanted layers into a BOX layer, a gas containing chlorine that is not less than 0.1 volume % but less than 1.0 volume % is mixed into an atmosphere during temperature elevation in the high-temperature heat treatment.

Abstract: There is disclosed a method for producing an epitaxial wafer with a buried diffusion layer comprising: implanting an impurity into a silicon single crystal wafer; subsequently diffusing the impurity in the wafer to form a diffusion layer; at least removing an oxide film on the diffusion layer; and thereafter forming a silicon epitaxial layer over the wafer to produce a silicon epitaxial wafer with a buried diffusion layer; wherein at least the oxide film on the diffusion layer is removed by etching with hydrofluoric acid to which a surfactant is added, and then the silicon epitaxial layer is formed. There can be provided a method for producing an epitaxial wafer with a buried diffusion layer in which generation of crystal defects in a silicon epitaxial layer is reduced effectively and an epitaxial wafer with a buried diffusion layer.

Abstract: There is provided a method for suppressing the occurrence of defects such as voids or blisters even in the laminated wafer having an oxide film of a thickness thinner than the conventional one, wherein hydrogen ions are implanted into a wafer for active layer having an oxide film of not more than 50 nm in thickness to form a hydrogen ion implanted layer, and ions other than hydrogen are implanted up to a position that a depth from the surface side the hydrogen ion implantation is shallower than the hydrogen ion implanted layer, and the wafer for active layer is laminated onto a wafer for support substrate through the oxide film, and then the wafer for active layer is exfoliated at the hydrogen ion implanted layer.

Abstract: On one face of a semiconductor wafer 1 having a first face (principal face) 1a and a second face (rear face) 1b, a protection film 2 is formed. When allowing the semiconductor wafer 1 to be attracted onto an attracting face of an electrostatic chuck 6 which is heated to 400° C. or more, the semiconductor wafer 1 is attracted onto the attracting face via the protection film 2. While heating the semiconductor wafer 1 to 400° C. or more, an ion implantation is performed for the face of the semiconductor wafer 1 on which the protection film 2 is not formed. Thereafter, the protection film 2 is removed from the semiconductor wafer 1.

Abstract: A semiconductor device is made by steps of removing portions of a first capping layer, removing portions of a sacrificial layer, recessing sidewalls, and forming fin structures. The step of removing portions of the first capping layer forms a first capping structure that covers portions of the sacrificial layer. The step of removing portions of the sacrificial layer removes portions of the sacrificial layer that are not covered by the first capping structure to define an intermediate structure. The step of recessing the sidewalls recesses sidewalls of the intermediate structure relative to edge regions of the first capping structure to form a sacrificial structure having recessed sidewalls. The step of forming fin structures forms fin structures adjacent to the recessed sidewalls.

Abstract: A semiconductor device includes a first semiconductor chip (5) having a first terminal (7) on one surface, a second semiconductor chip (1a) which is larger than the first semiconductor chip (5) and on which the first semiconductor chip (5) is stacked and which has a second terminal (3) on one surface, an insulating layer (10) formed on a second semiconductor chip (1a) to cover the first semiconductor chip (5), a plurality of holes (10a) formed in the insulating layer (10) on at least a peripheral area of the first semiconductor chip (5), a via (11a) formed like a film on inner peripheral surfaces and bottom surfaces of the holes (10a) and connected electrically to the second terminal (3) of the second semiconductor chip (1a), a wiring pattern (11b) formed on an upper surface of the insulating layer (10), and an external terminal (14) formed on the wiring pattern (11b).

Abstract: A technique for forming a film of material (12) from a donor substrate (10). The technique has a step of introducing energetic particles (22) through a surface of a donor substrate (10) to a selected depth (20) underneath the surface, where the particles have a relatively high concentration to define a donor substrate material (12) above the selected depth. An energy source is directed to a selected region of the donor substrate to initiate a controlled cleaving action of the substrate (10) at the selected depth (20), whereupon the cleaving action provides an expanding cleave front to free the donor material from a remaining portion of the donor substrate.

Abstract: A method of manufacturing a semiconductor element. A dislocation region is formed between a first layer and a second layer, the dislocation region including a plurality of dislocations. First interstitials in the first layer are at least partially eliminated using the dislocations in the dislocation region. Vacancies are formed in the second layer. Second interstitials in the second layer are at least partially eliminated using the vacancies in the second layer.

Abstract: A method of forming a buried interconnection includes removing a semiconductor substrate to form a groove in the semiconductor substrate. A metal layer is formed on inner walls of the groove using an electroless deposition technique. A silicidation process is applied to the substrate having the metal layer, thereby forming a metal silicide layer on the inner walls of the groove.

Abstract: A method for manufacturing a semiconductor device. The method includes providing a semiconductor body of a conductivity type, wherein the semiconductor body comprises a first surface. At least one buried region of a second conductivity type is formed in the semiconductor body and at least a surface region of the second conductivity type is formed at the first surface of the semiconductor body, wherein the buried region and the surface region are formed such that they are spaced apart from each other. The buried region is formed by deep implantation of a first dopant of the second conductivity type.

Abstract: The disclosure herein pertains to fashioning a low noise junction field effect transistor (JFET) where transistor gate materials are utilized in forming and electrically isolating active areas of a the JFET. More particularly, active regions are self aligned with patterned gate electrode material and sidewall spacers which facilitate desirably locating the active regions in a semiconductor substrate. This mitigates the need for additional materials in the substrate to isolate the active regions from one another, where such additional materials can introduce noise into the JFET. This also allows a layer of gate dielectric material to remain over the surface of the substrate, where the layer of gate dielectric material provides a substantially uniform interface at the surface of the substrate that facilitates uninhibited current flow between the active regions, and thus promotes desired device operation.

Abstract: A method is provided for forming a power semiconductor device. The method begins by providing a substrate of a second conductivity type and then forming a voltage sustaining region on the substrate. The voltage sustaining region is formed by depositing an epitaxial layer of a first conductivity type on the substrate and forming at least one terraced trench in the epitaxial layer. The terraced trench has a plurality of portions that differ in width to define at least one annular ledge therebetween. A barrier material is deposited along the walls of the trench. A dopant of a second conductivity type is implanted through the barrier material lining the annular ledge and said trench bottom and into adjacent portions of the epitaxial layer. The dopant is diffused to form at least one annular doped region in the epitaxial layer and at least one other region located below the annular doped region.

Abstract: A MLD-SIMOX wafer is obtained by forming a first ion-implanted layer in a silicon wafer; forming a second ion-implanted layer that is in an amorphous state; and subjecting the wafer to a high-temperature heat treatment to maintain the wafer in an atmosphere containing oxygen at a temperature that is not lower than 1300° C. but lower than a silicon melting point to change the first and the second ion-implanted layers into a BOX layer, wherein the dose amount for the first ion-implanted layer is 1.25 to 1.5×1017 atoms/cm2, the dose amount for the second ion-implanted layer is 1.0×1014 to 1×1016 atoms/cm2, the wafer is preheated to a temperature of 50° C. to 200° C. before forming the second ion-implanted layer, and the second ion-implanted layer is formed in a state where it is continuously heated to a preheating temperature.

Abstract: A method for manufacturing a solid state imaging device includes steps of forming a photodiode layer buried in a semiconductor substrate by ion injection and of forming a shielding layer buried in the photodiode layer by ion injection. At least in the ion injection process in the step of forming the shielding layer, an ion injection pause period is provided at least one time during whole ion injection step. According to the method, crystal defects are prevented from generating even if ion injection is performed with high energy, thereby suppressing dark current without complexity in manufacturing process.

Abstract: A semiconductor device suitable for a source-follower circuit, provided with a gate electrode formed on a semiconductor substrate via a gate insulation film, a first conductivity type layer formed in the semiconductor substrate under a conductive portion of the gate electrode and containing a first conductivity type impurity, first source/drain regions of the first conductivity type impurity formed in the semiconductor substrate and extended from edge portions of the gate electrode, and second source/drain regions having a first conductivity type impurity concentration lower than that in the first source/drain regions and formed adjoining the gate insulation film and the first source/drain regions in the semiconductor substrate so as to overlap portions of the conductive portion of the gate electrode.

Abstract: Method of fabricating a varactor that includes providing a semiconductor substrate, doping a lower region of the semiconductor substrate with a first dopant at a first energy level, doping a middle region of the semiconductor substrate with a second dopant at a second energy level lower than the first energy level, and doping an upper region of the semiconductor substrate with a third dopant at a third energy level lower than the second energy level.

Abstract: A far subcollector, or a buried doped semiconductor layer located at a depth that exceeds the range of conventional ion implantation, is formed by ion implantation of dopants into a region of an initial semiconductor substrate followed by an epitaxial growth of semiconductor material. A reachthrough region to the far subcollector is formed by outdiffusing a dopant from a doped material layer deposited in the at least one deep trench that adjoins the far subcollector. The reachthrough region may be formed surrounding the at least one deep trench or only on one side of the at least one deep trench. If the inside of the at least one trench is electrically connected to the reachthrough region, a metal contact may be formed on the doped fill material within the at least one trench. If not, a metal contact is formed on a secondary reachthrough region that contacts the reachthrough region.

Abstract: An structure for electrically isolating a semiconductor device is formed by implanting dopant into a semiconductor substrate that does not include an epitaxial layer. Following the implant the structure is exposed to a very limited thermal budget so that dopant does not diffuse significantly. As a result, the dimensions of the isolation structure are limited and defined, thereby allowing a higher packing density than obtainable using conventional processes which include the growth of an epitaxial layer and diffusion of the dopants. In one group of embodiments, the isolation structure includes a deep layer and a sidewall which together form a cup-shaped structure surrounding an enclosed region in which the isolated semiconductor device may be formed. The sidewalls may be formed by a series of pulsed implants at different energies, thereby creating a stack of overlapping implanted regions.

Abstract: In a non-volatile memory structure, the source/drain regions are surrounded by a nitrogen-doped region. As a result, an interface between the substrate and the charge trapping layer above the nitrogen-doped region is passivated by a plurality of nitrogen atoms. The nitrogen atoms can improve data retention, and performance of cycled non-volatile memory devices.

Abstract: A MOS varactor includes a shallow PN junction beneath the surface of the substrate of a MOS structure. In depletion mode, the depletion region of the MOS structure merges with the depletion region of the shallow PN junction. This increases the total width of the depletion region of the MOS varactor to reduce Cmin.