Abstract: Some structures and methods to reduce power consumption in devices can be implemented largely by reusing existing bulk CMOS process flows and manufacturing technology, allowing the semiconductor industry as well as the broader electronics industry to avoid a costly and risky switch to alternative technologies. Some of the structures and methods relate to a Deeply Depleted Channel (DDC) design, allowing CMOS based devices to have a reduced sVT compared to conventional bulk CMOS and can allow the threshold voltage VT of FETs having dopants in the channel region to be set much more precisely. The DDC design also can have a strong body effect compared to conventional bulk CMOS transistors, which can allow for significant dynamic control of power consumption in DDC transistors. Additional structures, configurations, and methods presented herein can be used alone or in conjunction with the DDC to yield additional and different benefits.

Abstract: A method for selective deposition of Si or SiGe on a Si or SiGe surface exploits differences in physico-chemical surface behavior according to a difference in doping of first and second surface regions. By providing at least one first surface region with a Boron doping of a suitable concentration range and exposing the substrate surface to a cleaning and passivating ambient atmosphere in a prebake step at a temperature lower or equal than 800° C., a subsequent deposition step of Si or SiGe will not lead to a layer deposition in the first surface region. This effect is used for selective deposition of Si or SiGe in the second surface region, which is not doped with Boron in the suitable concentration range, or doped with another dopant, or not doped. Several devices are, thus, provided. The method thus saves a usual photolithography sequence required for selective deposition of Si or SiGe in the second surface region according to the prior art.

Abstract: A semiconductive device is fabricated by forming, within a semiconductive substrate, at least one continuous region formed of a material having a non-uniform composition in a direction substantially perpendicular to the thickness of the substrate.

Abstract: A method for selective deposition of Si or SiGe on a Si or SiGe surface exploits differences in physico-chemical surface behavior according to a difference in doping of first and second surface regions. By providing at least one first surface region with a Boron doping of a suitable concentration range and exposing the substrate surface to a cleaning and passivating ambient atmosphere in a prebake at a temperature lower or equal to 800° C., a subsequent deposition step will prevent deposition in the first surface region. This allows selective deposition in the second surface region, which is not doped with the Boron (or doped with another dopant or not doped). Several devices are, thus, provided. The method saves a usual photolithography sequence, which according to prior art is required for selective deposition of Si or SiGe in the second surface region.

Abstract: An integrated circuit and method for making an integrated circuit including doping a semiconductor body is disclosed. One embodiment provides defect-correlated donors and/or acceptors. The defects required for this are produced by electron irradiation of the semiconductor body. Form defect-correlated donors and/or acceptors with elements or element compounds are introduced into the semiconductor body.

Abstract: A semiconductor device and a method of manufacturing a semiconductor device. A method of manufacturing a semiconductor device may include forming a gate electrode over a semiconductor substrate, a second conductive type ion implantation region at opposite sides of a gate electrode, a second conductive type ion implantation region as a first conductive type second ion implantation region by implanting a first conductive type impurity over opposite sides of said gate electrode, and/or forming a first conductive type first ion implantation region that substantially surrounds a first conductive type second ion implantation region. A method of manufacturing a semiconductor device may form an N type MOSFET and/or a P type MOSFET using a single photolithography process for each N+ source/drain photolithography process and/or P+ source/drain photolithography process.

Abstract: The invention relates to a method for selective deposition of Si or SiGe on a Si or SiGe surface. The method exploits differences in physico-chemical surface behavior according to a difference in doping of first and second surface regions. By providing at least one first surface region with a Boron doping of a suitable concentration range and exposing the substrate surface to a cleaning and passivating ambient atmosphere in a prebake step at a temperature lower or equal than 800° C., a subsequent deposition step of Si or SiGe will not lead to a layer deposition in the first surface region. This effect is used for selective deposition of Si or SiGe in the second surface region, which is not doped with Boron in the suitable concentration range, or doped with another dopant, or not doped. The method thus saves a usual photolithography sequence required for selective deposition of Si or SiGe in the second surface region according to the prior art.

Abstract: The present invention provides a method of forming a bipolar transistor. The method includes doping a silicon layer with a first type of dopant and performing a first implant process to implant dopant of a second type opposite the first type in the silicon layer. The implanted dopant has a first dopant profile in the silicon layer. The method also includes performing a second implant process to implant additional dopant of the second type in the silicon layer. The additional implanted dopant has a second dopant profile in the silicon layer different than the first dopant profile. The method further includes growing an insulating layer formed over the silicon layer by consuming a portion of the silicon layer and the first type of dopant.

Abstract: Methods are disclosed for forming a varied impurity profile for a collector using scattered ions while simultaneously forming a subcollector. In one embodiment, the invention includes: providing a substrate; forming a mask layer on the substrate including a first opening having a first dimension; and substantially simultaneously forming through the first opening a first impurity region at a first depth in the substrate (subcollector) and a second impurity region at a second depth different than the first depth in the substrate. The breakdown voltage of a device can be controlled by the size of the first dimension, i.e., the distance of first opening to an active region of the device. Numerous different sized openings can be used to provide devices with different breakdown voltages using a single mask and single implant. A semiconductor device is also disclosed.

Abstract: A semiconductor device has a configuration in which more than three kinds of wells are formed with small level differences. One kind of well from among the more than three kinds of wells has a surface level higher than other kinds of wells from among the more than three kinds of wells. The one kind of well is formed adjacent to and self-aligned to at least one kind of well from among the other kinds of wells. The other kinds of wells are different in one of a conductivity type, an impurity concentration and a junction depth, and include at least two kinds of wells having the same surface level.

Abstract: According to one embodiment of the present invention, a method of forming a semiconductor device is provided, the method including: forming a substrate; forming a first gate on the substrate; forming a mask layer on the substrate, the mask layer including a first window covering an area within which the first gate is formed so that the first gate divides the substrate exposed by the first window into a first region and a second region; and doping the exposed substrate using rays inclined with respect to the substrate top surface, where the position of the first gate with respect to a border of the first window is chosen such that the inclined doping rays impinge more on the first region than on the second region.

Abstract: A metal oxide semiconductor (MOS) transistor is disclosed. The MOS transistor includes: a semiconductor substrate; a gate disposed on the semiconductor substrate, wherein the gate comprises two sidewalls; a spacer formed on the sidewalls of the gate; a source/drain region disposed in the semiconductor substrate; a silicide layer disposed on top of the gate and the surface of the source/drain region; and a retarded interface layer disposed in the junction between the silicide layer and the gate and source/drain region.

Abstract: A method of manufacturing a semiconductor device that includes forming a gate dielectric layer over a semiconductor substrate. A gate electrode is formed over the gate dielectric layer. A dopant is implanted into an extension region of the substrate, with an amount of the dopant remaining in a dielectric layer adjacent the gate electrode. The substrate is annealed at a temperature of about 1000° C. or greater to cause at least a portion of the amount of the dopant to diffuse into the semiconductor substrate.

Abstract: A boron ion stream may be used to implant ions, such as boron ions, into the sidewalls of an active area, such as an NFET active area. The boron ion stream has both vertical tilt and horizontal rotation components relative to the sidewalls and/or the silicon device, to provide a better line of sight onto the sidewalls. This may allow components of the silicon device to be moved closer together without unduly reducing the effectiveness of boron doping of NFET active area sidewalls, and provides an improved line of sight of a boron ion stream onto the sidewalls of an NFET active area prior to filling the surrounding trench with STI material.

Abstract: A semiconductor device has a substrate and a dielectric film formed directly or indirectly on the substrate. The dielectric film contains a metal silicate film, and a silicon concentration in the metal silicate film is lower in a center portion in the film thickness direction than in an upper portion and in a lower portion.

Abstract: A method of performing salicide processes on a MOS transistor, wherein the MOS transistor comprises a gate structure and a source/drain region, the method comprising: performing a selective growth process to form a silicon layer on the top of the gate and the source/drain region; performing an ion implantation process to form a retarded interface layer between the silicon layer and the gate and source/drain region; forming a metal layer on the silicon layer; and reacting the metal layer with the silicon layer for forming a silicide layer.

Abstract: Disclosed is a method of forming a transistor in an integrated circuit structure that begins by forming a collector in a substrate and an intrinsic base above the collector. Then, the invention patterns an emitter pedestal for the lower portion of the emitter on the substrate above the intrinsic base. Before actually forming the emitter or associates spacer, the invention forms an extrinsic base in regions of the substrate not protected by the emitter pedestal. After this, the invention removes the emitter pedestal and eventually forms the emitter where the emitter pedestal was positioned.

Abstract: The invention relates to a method for producing integrable semiconductor components, especially transistors or logic gates, using a p-doped semiconductor substrate. First of all, a mask is applied to the semiconductor substrate in order to define a window that is delimited by a peripheral edge. An n-doped trough is then produced in the semiconductor substrate by means of ion implantation using an energy that is sufficient for ensuring that a p-doped inner area remains on the surface of the semiconductor substrate. The edge area of the n-doped trough extends as far as the surface of the semiconductor substrate. The other n-doped and/or p-doped areas that make up the structure of the transistor or logic gate are then inserted into the p-doped inner area of the semiconductor substrate. The inventive method is advantageous in that it no longer comprises expensive epitaxy and insulation processes. In an n-doped semiconductor substrate, all of the implanted ions are replaced by the complementary species; i.e.

Abstract: A method to achieve controlled conductivity in microfluidic devices, and a device formed thereby. The method comprises forming a microchannel or a well in an insulating material, and ion implanting at least one region of the insulating material at or adjacent the microchannel or well to increase conductivity of the region.

Abstract: A varactor designed to enable voltage controlled oscillator (VCO) integration in wireless systems is the base-emitter junction of a specially optimized NPN device formed with a double base implant. A first, shallow implant optimizes capacitance, leakage current, and tuning range. A second, deeper base implant is used to improve the quality factor of the device by reducing the base resistance. The varactor includes a third terminal (collector), which isolates the emitter-base junction from the substrate, providing flexibility in circuit applications. A method for fabricating a high performance varactor having the above-described structure is also provided.

Abstract: A Si1-xGex layer 111b functioning as the base composed of an i—Si1-xGex layer and a p+ Si1-xGex layer is formed on a collector layer 102, and a Si cap layer 111a as the emitter is formed on the p+ Si1-xGex layer. An emitter lead electrode 129, which is composed of an n? polysilicon layer 129b containing phosphorus in a concentration equal to or lower than the solid-solubility limit for single-crystal silicon and a n+ polysilicon layer 129a containing phosphorus in a high concentration, is formed on the Si cap layer 111a in a base opening 118. The impurity concentration distribution in the base layer is properly maintained by suppressing the Si cap layer 111a from being doped with phosphorus (P) in an excessively high concentration. The upper portion of the Si cap layer 111a may contain a p-type impurity. The p-type impurity concentration distribution in the base layer of an NPN bipolar transistor is thus properly maintained.

Abstract: The present invention provides a highly doped semiconductor layer.

Abstract: A manufacture method of a semiconductor device, and more particularly to the manufacture method of a silicon/silicon-germanium heterogeneous bipolar transistor (HBT) device with ultra-thin base, which mainly utilized the method of doping carbon atoms in the silicon-germanium (SiGe) spacer layer in order to suppress the out-diffusion of boron, increase the amount of doped boron in base, germanium (Ge) concentration, and critical thickness, and decrease the thickness of silicon-germanium spacer layer, and achieve the objective of raising the device's high frequency property.

Abstract: During the production of integrated semiconductor structures, it is often necessary to differently dope immediately adjacent regions. A method is provided for producing two adjacent regions of a predetermined area in an integrated semiconductor, whereby a first region of the two adjacent regions includes a doping with a lower target concentration than a second region. The predetermined area of a semiconductor blank is doped with a dopant until a concentration of the dopant is obtained that is at least as high as the target concentration of the second region. A protective layer is applied to the second region, and the dopant is out-diffused from the first region until a concentration of dopant is obtained that corresponds to the target concentration of the first region.

Abstract: There is provided a method of manufacturing a semiconductor device which can use commonly a part of a step of forming a PAP transistor with a step of forming an NON transistor. In an area separated by a side separation region (5) of PNP formed by doping N-type impurities simultaneously with the formation of the collector region (4) of NPN, an N-type bottom separation region (8) of PNP, a collector region (9) and a base region (10) are formed by using the same mask. Trenches (18, 17) extending to the collector regions (9, 4) are formed by an over-etching treatment carried out when the emitter electrodes (16, 15) of PNP and NPN are subjected to a patterning treatment, and N-type impurities are doped through the trench (17) simultaneously with the formation of an external base region (20) of PNP, thereby forming a collector drawing region (21) of NPN.

Abstract: A system and method for controlling a characteristic of at least one memory cell on a semiconductor is disclosed. The at least one memory cell includes a gate stack, a source, and a drain. The semiconductor includes a surface. In one aspect, the method and system include providing the gate stack on the semiconductor and providing the source including a source dopant having a local peak in concentration. The local peak in concentration of the source dopant is located under the gate stack and in proximity to a portion of the surface of the semiconductor. In another aspect the method and system includes a memory cell on a semiconductor. The semiconductor includes a surface. The memory cell includes a gate stack on the semiconductor, a source, and a drain. The gate stack has a first edge and a second edge. The source is located in proximity to the first edge of the gate stack. The drain is located in proximity to the second edge of the gate stack. A first portion of the source is disposed under the gate stack.

Abstract: Provided with a semiconductor device including: a semiconductor substrate having a first conductivity type; a first well having a second conductivity type formed in a first region in a major surface of the semiconductor substrate; a second well having the first conductivity type formed in a second region in the major surface of the semiconductor substrate; a first MOS transistor having the first conductivity type and a first contact region having the second conductivity type formed in the first well; a second MOS transistor having the second conductivity type and a second contact region having the second conductivity type formed in the second well; a heavily doped region of buried layer having the second conductivity type formed at a portion corresponding to the first contact region in the first well; and a heavily doped region of buried layer having the first conductivity type formed at a portion corresponding to the second contact region in the second well.

Abstract: A photoresist pattern is formed on a field oxide film and an element forming region across the field oxide film and the element forming region such that a portion of a surface of the field oxide film and a portion of a surface of a silicon epitaxial layer are continuously exposed. The photoresist pattern is used as a mask to inject boron ions into the silicon epitaxial layer and heat treatment is performed thereon to form an external base containing the relatively significant crystal defect present in the silicon epitaxial layer in the vicinity of the field oxide film. Thus, a semiconductor device can be obtained including a bipolar transistor which provides improved breakdown voltage between the collector and the base and contemplates reduction of current leakage.

Abstract: Integrated circuitry and methods of forming integrated circuitry are described. In one implementation, a common masking step is utilized to provide source/drain diffusion regions and halo ion implantation or dopant regions relative to the source/drain regions within one well region of a substrate; and well contact diffusion regions within another well region of the substrate. The common masking step preferably defines at least one mask opening over the substrate within which the well contact diffusion region is to be formed, and the mask opening is suitably dimensioned to reduce the amount of halo ion implantation dopant which ultimately reaches the substrate therebelow. According to one aspect, a plurality of mask openings are provided. According to another aspect, a suitably-dimensioned single mask opening is provided.

Abstract: A fabrication method for a MOSFET device including the steps of forming a first insulating film on a semiconductor substrate wherein an active region and an isolated region are defined, forming a channel ion region by implanting impurity ions into the active region of the semiconductor substrate, forming a first conductive film pattern on a portion of the semiconductor substrate which corresponds to the channel ion region, forming a channel region having lower concentration than the channel ion region by implanting impurity ions in a different type from the ions in the channel ion region into a center portion of the channel ion region through the first conductive film pattern, forming a second conductive film pattern on the first conductive film pattern, forming an impurity region of low concentration in the semiconductor substrate with the first and second conductive film patterns as a mask, forming a sidewall spacer at both sides of the first and second conductive film patterns, and forming an impurity regi

Abstract: A bipolar transistor compatible with CMOS processes utilizes only a single layer of polysilicon while maintaining the low base resistance associated with conventional double-polysilicon bipolar designs. Dopant is implanted to form the intrinsic base through the same dielectric window in which the polysilicon emitter contact component is later created. Following poly deposition within the window and etch to create the polysilicon emitter contact component, large-angle tilt ion implantation is employed to form a link base between the intrinsic base and a subsequently-formed base contact region. Tilted implantation enables the link base region to extend underneath the edges of the polysilicon emitter contact component, creating a low resistance path between the intrinsic base and the extrinsic base. Fabrication of the device is much simplified over a conventional double-poly transistor, particularly if tilted implantation is already employed in the process flow to form an associated structure such as an LDMOS.

Abstract: A semiconductor device having an electrostatic discharge protection device and at least one accompanying device selected from the group comprising of a N or P channel MOS transistor, CMOS, bipolar transistor and BiCMOS, in which the electrostatic discharge protection device comprises a vertical type bipolar transistor including; a semiconductor substrate; an epitaxial layer laminated on the semiconductor substrate; a buried collector of a first conductivity type which is formed of the semiconductor substrate or which is formed from the surface of the semiconductor substrate to the epitaxial layer; a base of a second conductivity type which is a lightly doped well and formed on the epitaxial layer; and an emitter of the first conductivity type and formed on the surface layer of the base of the second conductivity type; and in which the base is adapted to have impurity concentration and depth so that a punch-through is generated between the emitter and the collector of the electrostatic discharge protection dev

Abstract: A semiconductor device is provided in which a vertical NPN transistor and a vertical PNP transistor electrically isolated from each other are formed on a p-type semiconductor substrate. An n-type buried separating region of the vertical PNP transistor is formed by high-energy ion implantation after formation of the n.sup.+ type buried collector region of the vertical NPN transistor, and a p.sup.+ type buried collector region of the vertical PNP transistor is formed subsequently to formation of an n-type epitaxial layer and a device separating region whereby the thickness of the n-type epitaxial layer is optimized to a required minimum value. A method for producing a semiconductor device is also provided in which a first vertical bipolar transistor of a first conductivity type and a second vertical bipolar transistor of a second conductivity type, electrically isolated from each other, are formed on a semiconductor substrate having a pre-set conductivity type.

Abstract: The occupied area of a heater drive circuit of a recording head is reduced, and the number of manufacturing steps is decreased. As a circuitry of the heater drive unit, the final stage of the drive unit is constituted of a pnp or npn bipolar transistor, the heater, which is a load, is connected to the emitter side, and the collectors of each transistor are connected commonly to the base itself and grounded. The prestage of the drive unit is formed of the prestage of a MOS type element whose polarities are reversed to those of the final stage, i.e., an n-type MOS transistor with respect to the final stage of a pnp bipolar transistor and a p-type MOS transistor with respect to the final stage of a npn bipolar transistor, and the source of the prestage is grounded.

Abstract: A bipolar transistor with a relatively deep emitter region is formed in a BICMOS device using the source/drain mask used to form the source and drain regions of MOSFETs of the device and the base region mask which would otherwise be required in any event to diffuse an emitter region of the bipolar transistor. The emitter is diffused or implanted to a depth greater than the depth to which a source and a drain region of the MOSFET are diffused. By using only the base region and source/drain region masks, and developing in sequence, each of two coatings of photoresist applied on top of one another, an access opening to the emitter region is define solely by the co-location of openings in each of the two coatings, thereby allowing the emitter region to be separately and additionally implanted. The access to the base region for the additional implication is achieved using only a few additional photo-ops and not as a result of using an additional emitter mask.

Abstract: Zener diode with high stability in time and low noise for integrated circuits and provided in an epitaxial pocket insulated from the rest of a type N epitaxial layer grown on a substrate of type P semiconductor material.In said pocket are included a type N+ cathode region and a type P anode region enclosing it.The cathode region has a peripheral part surrounding a central part extending in the anode region less deeply than the peripheral part.

Abstract: A semiconductor processing method of providing dopant impurity into a semiconductor substrate includes: a) providing a semiconductor substrate, the substrate comprising a first bulk region having a blanket doping of a first conductivity type dopant, the substrate comprising a second bulk region having a blanket doping of a second conductivity type dopant; b) defining field oxide regions and active area regions in each of the first and second bulk substrate regions; c) in the same masking step, masking active area regions of the first bulk substrate region while leaving field oxide regions of the first bulk substrate region unmasked and masking field oxide regions of the second bulk substrate region while leaving select active area regions of the second bulk substrate region unmasked; and d) in the same ion implanting step, ion implanting first conductivity type impurity through the unmasked portions of the first and second bulk substrate regions to simultaneously form channel stop isolation implants beneath t