Abstract: A BiCMOS process where a base region is formed in a relatively highly doped n-type substrate region. Boron is implanted at two different energy levels to form the base region and a counter doped n region near the base collector junction to prevent impact ionization.

Abstract: A bipolar fabrication process, illustratively suited for integration into a conventional CMOS process to thereby form a BiCMOS integrated circuits is disclosed. The collector and base are formed through multiple implants and a single masking step to thereby provide a continuous low resistance collector region.

Abstract: In a semiconductor device manufacturing method for forming first and second bipolar transistors on a semiconductor substrate 1, a link base layer 5 for connecting a graft base layer (graft base layer 8) of the first bipolar transistor and an intrinsic base layer 12 to each other, and at least a part of a base layer 6 of the second bipolar transistor are formed simultaneously with each other, and then the link base layer 5 in a region where the intrinsic base layer 12 will be formed is removed by an etching treatment, and then by a selective epitaxial growth method, the intrinsic base layer 12 is formed in the region where the link base layer 5 is removed.

Abstract: A polysilicon emitter of a bipolar device is formed utilizing a self-aligned Damascene technique. An oxide mask is patterned over epitaxial silicon implanted to form the intrinsic base. The oxide mask is then etched to form a window. Polysilicon is uniformly deposited over the oxide mask and into the window. The polysilicon is then polished to remove polysilicon outside of the window. Etching of the oxide mask follows, with good selectivity of oxide over silicon. This selectivity produces a polysilicon emitter atop an intrinsic base, the base flush with the silicon surface rather than recessed because of overetching associated with conventional processes.

Abstract: A vertical PNP transistor (11) and method for making it includes forming an N- region (19) in a P substrate (12), and forming an N+ region (26) in the substrate (12) laterally surrounding and partially extending into the N- region (19). A P region (30) is formed above the N- region (19), bounded laterally by the N+ region (26) to be horizontally and vertically isolated from the substrate (12) by the N- and N+ regions (19 and 26). A layer of semiconductor material (32) is formed overall, and an N well (35) and a surrounding P well (36) are formed, each extending to the P region (30). An isolating N+ well (38) is formed surrounding the P well (36), extending to the buried N+ region (26). A P emitter region (40) and an N base contact region (41) are formed at a surface of the N well (35), and a P collector contact region (44) is formed at a surface of the P well (36).

Abstract: A semiconductor device and a manufacturing method therefor which can simultaneously realize both a reduction in base transit time by a reduction in base width and a reduction in base resistance by a reduction in link base resistance. The semiconductor device is manufactured by the method including the steps of forming a first impurity diffused layer of a first conduction type in a semiconductor substrate; forming a conducting film connected to the first impurity diffused layer; forming a first insulating film on the conducting film; forming a first hole through a laminated film composed of the first insulating film and the conducting film; forming a second impurity diffused layer of the first conduction type in the semiconductor substrate exposed to the first hole; forming a side wall from a second insulating film in the first hole to form a second hole; and forming a third impurity diffused layer of the first conduction type in the semiconductor substrate exposed to the second hole.

Abstract: An embodiment of the present invention is a process for semiconductor device having a silicon substrate. The process comprises positioning at least one field implant mask and field implanting a silicon substrate around a bipolar active region in a substrate such that boron atoms are blocked out of an active region, and only the field region surrounding the active area is implanted, the implanting such that a predetermined layout area of a semiconductor device does not need to be increased to compensate for a BV.sub.bso problem.

Abstract: A method of producing a bipolar transistor includes the step of forming an emitter contact layer containing a high concentration of impurity by means of plasma doping or solid-state diffusion without causing diffusion of impurity in a base layer. This makes it possible to realize a thin base layer having a high impurity concentration.The invention also provides a method of producing a semiconductor device including a bipolar transistor and another device element such as a resistor element including a polysilicon layer containing an activated impurity in such a manner that both the bipolar transistor and the device element are disposed on the same single substrate, the method including the steps of: forming a polysilicon layer containing an activated impurity on the surface of a substrate; and then forming a base layer of the bipolar transistor. This method prevents the base layer from being affected by heat treatment on the polysilicon layer.

Abstract: A two masking level process for a dual buried region epitaxial architecture forms a first masking layer on a surface of a P type substrate. The first masking layer exposes first and second surface portions of the substrate for N+ and P+ buried regions. N type impurities are introduced into the substrate through the first masking layer, so as to form N+ doped regions. A second masking layer is then selectively formed on the first masking layer, such that the second masking layer masks the first aperture, but exposes a second portion of the first masking layer that both includes and surrounds the second aperture. Boron impurities are then introduced through the exposed second aperture of the first masking layer, to a P+ doping concentration.

Abstract: A capacitor coupled contactless imager structure and method of manufacturing the structure results in a phototransistor that includes an N-type collector region formed in P-type semiconductor material. A P-type base region is formed in the collector region. An n-doped polysilicon emitter contact is formed in contact with the surface of the P-type base region such that an n+ epitaxial region is formed in the base region as the emitter of the imager phototransistor. Silicon dioxide separates the polysilicon emitter contact and exposed surfaces of the base region from a layer of poly2 about 500-600 .ANG. thick that is formed to cover the entire base region.

Abstract: A bipolar transistor has a performance and high reliability, which are by enhancing a withstand voltage between an emitter and a base. The bipolar transistor includes a first impurity diffusion layer in a semiconducting substrate, a first conductive film connected to the first diffusion layer, and an opening disposed in the first conductive film. A second impurity diffusion layer is formed in a portion, exposed from the opening portion, of the semiconducting substrate and is connected to the first impurity diffusion layer. A third impurity diffusion layer is formed so as to contain the second diffusion layer and side walls are formed on the side walls of the opening. A fourth impurity diffusion layer is formed in the third impurity diffusion layer in the opening surrounded by the side walls.

Abstract: In a method of fabricating a self-aligned bipolar junction transistor with silicide extrinsic base contacts and selective epitaxial grown intrinsic base region, the sinker and buried N+ layer regions are formed in a semiconductor substrate with trench oxide isolation. Thin oxide is then formed on the structure. Next, metal silicide is deposited on the thin oxide and p-dopant implanted into the silicide. LTO is then deposited on the doped silicide followed by deposition of nitride. Next, the nitride, LTO and silicide layers are etched, stopping on the thin oxide layer. The thin oxide is then etched to expose the silicon. The etch undercuts the thin oxide under the nitride. A thin p+ epitaxial base is then selectively grown on the silicon and the metal silicide only. The base can be silicon or a silicon germanium layer to form a heterojunction transistor. Next, thin LTO is deposited followed by deposition of nitride. An RIE of the nitride is then performed to form nitride spacers, stopping on the thin LTO.

Abstract: A heterejunction bipolar transistor and a method for fabricating an HBT with self-aligned base metal contacts using a double photoresist, which requires fewer process steps than known methods, while minimizing damage to the active emitter contact region. In particular, a photoresist is used to form the emitter mesa. The emitter mesa photoresist is left on and a double polymethylmethacrylate (PMMA) and photoresist layer is then applied. The triple photoresist combination is patterned to create a non-critical lateral alignment for the base metal contacts to the emitter mesa, which permits selective base ohmic metal deposition and lift-off. By utilizing the double photoresist as opposed to a metal or dielectric for masking, an additional photolithography step and etching step is eliminated. By eliminating the need for an additional etching step, active regions of the semiconductors are prevented from being exposed to the etching step and possibly damaged.

Abstract: A bipolar transistor is provided whose emitter surrounds the base. The transistor has in some embodiments a high ratio of the emitter area to the base area and low collector and emitter resistances. Further, a transistor is provided in which a collector contact region is surrounded by the base. Consequently, a low collector resistance is obtained in some embodiments.

Abstract: Methods of forming bipolar junction transistors include the steps of forming a first insulating layer on a face of a semiconductor substrate containing a collector region of first conductivity type therein and then forming an opening in the first insulating layer to expose the collector region at the face. An extrinsic base region contact layer of second conductivity type is then formed on the first insulating layer and in the opening and then an extrinsic base region of second conductivity type is formed in the collector region, at the opening in the first insulating layer. Next, a second insulating layer is formed on the extrinsic base region contact layer and first insulating layer, using the first insulating layer as a mask to prevent contact between the second insulating layer and the collector region at the face.

Abstract: Method and apparatus for improving the high current operation of bipolar transistors while minimizing adverse affects on high frequency response are disclosed. A local implant to increase the doping of the collector at the collector to base interface is achieved by the use of an angled ion implant of collector impurities through the emitter opening. The resulting area of increased collector doping is larger than the emitter opening, which minimizes carrier injection from the emitter to the collector, but is smaller than the area of the base.

Abstract: In a semiconductor apparatus having a PNP bipolar transistor and high voltage resistance, there is formed an oxide insulating layer in the surface region of a P-type semiconductor substrate. In the above semiconductor substrate is formed a P-type collector layer so that at least a part of the P-type collector layer is in contact with said oxide insulating layer. In the surface region of said P-type collector layer is formed a P-type collector contact layer. An N-type base layer is formed in that region on the surface side of said P-type collector layer in which said P-type collector contact layer does not exist. A P-type emitter layer is formed on the surface side of said N-type base layer.

Abstract: High-performance bipolar transistors with improved wiring options and fabrication methods therefore are set forth. The bipolar transistor includes a base contact structure that has multiple contact pads which permit multiple device layouts when wiring to the transistor. For example, a first device layout may comprise a collector-base-emitter device layout, while a second device layout may comprise a collector-emitter-base device layout. More specifically, the base contact structure at least partially surrounds the emitter and has integral contact pads which extend away from the emitter. Further, sections of the base contact structure are disposed on an insulating layer outside of the perimeter of the base region of the transistor, while other sections directly contact the base region. Specific details of the bipolar transistor, and fabrication methods therefore are also set forth.

Abstract: Parts of the emitter and base of a vertical bipolar transistor adjoin a field-isolation region to form a walled-emitter structure. The transistor is furnished with extra doping in the collector and, optionally, in the base. The extra collector doping is provided along collector-base junction below the intrinsic base to create a special collector zone spaced laterally apart from the field-isolation region. The presence of the special collector zone causes the intrinsic base to be thinner, thereby raising the cutoff frequency and overall current gain. The extra base doping is provided in the intrinsic base along the field-isolation region to improve the transistor's breakdown voltage and leakage current characteristics.

Abstract: A self-aligned planar heterojunction bipolar transistor (10) is fabricated by forming a base layer (18) and forming an emitter layer (20) on the base layer (18). An emitter cap layer (22) is formed on the emitter layer (20) and an interface layer (24) is formed on the emitter cap layer (22). A first implantation layer (26) is formed through the interface layer (24), the emitter cap layer (22), and the emitter layer (20) to the base layer (18). A second implantation layer (30) is formed through the interface layer (24), the emitter cap layer (22), and the emitter layer (20) to the base layer (18) and overlaps the first implantation layer (26). A portion of the interface layer (24), the emitter cap layer (22), and the implantation layers (26, 30) are removed and replaced by an insulating region (33). An emitter contact (38) is formed on the remaining emitter cap layer (22) and is isolated from the implantation layers (26, 30) by the insulating region (33).

Abstract: Indium doping is used to make bases of bipolar transistors with superior operational characteristics.

Abstract: This is a method of making a semiconductor device comprising covering a first semiconductor compound having a plurality of windows on a major surface of a semiconductor body, covering a second semiconductor compound on selected windows of the first compound, forming openings in the second compound over the selected windows, forming electrodes by introducing an impurity in the semiconductor body through the openings.

Abstract: A method for reproducibly fabricating a thin base region of a vertical bipolar transistor therein, which has a high transfer speed and increases a current driving force, and a method for increasing the isolating effect of the vertical bipolar transistor through forming a second buried layer implanting N-type impurity into an upper peripheral portion of first buried layer and activating the implanted N-type impurity, then out-diffusing the activated N-type impurity at the same time as growing the epitaxial layer, so the second buried layer definitely separates the elements of the transistor. Both the first buried layer and the second buried layer define a portion of epitaxial layer to form an active region which functions as a collector region. A subcollector region is formed above first buried layer in active region, and a base region is formed at a first upper portion of the active region to overlay the subcollector region.

Abstract: A method for fabricating an HBT in which the subcollector-base junction, which contributes to the base-collector capacitance of the device, is reduced by using a selective subcollector. In particular, subcollector areas of the device that do not contribute to collector resistance reduction are eliminated, thereby reducing the subcollector area, which, in turn, reduces the base-collector capacitance. As such, the maximum power-gain frequency f.sub.max is increased.

Abstract: A self-aligned semiconductor component (10) includes a layer (14) having two openings (36, 38) and overlying a doped region (13) in a substrate (11). One (36) of the two openings (36, 38) is used to self-align a different doped region (22) and a portion (27) of an electrode (27, 31). The electrode (27, 31) has another portion (31) overlying the self-aligned portion (27) to increase the current carrying capacity of the electrode (27, 31). A different electrode is formed in the other one (38) of the two openings (36, 38) and has a smaller current carrying capacity than the other electrode (27, 31).

Abstract: The present invention teaches a method for fabricating a bipolar junction transistor ("BJT") from a semiconductor substrate having a base region, wherein the BJT comprises an increased Early voltage. The method initially comprises the step of forming a patterned interlevel dielectric layer superjacent the substrate such that a segment of the substrate is exposed. Subsequently, a contact comprising a material having a grain size smaller than polycrystalline silicon is formed superjacent the patterned interlevel dielectric layer and the segment of the substrate exposed. The contact is then implanted with a dopant. Once implanted, the substrate is annealed to enable the dopant to diffuse from the contact into the base region impeded by the grain size to form an emitter region and thereby increase the Early voltage of the bipolar junction transistor.

Abstract: In a method of manufacturing a bipolar transistor, a collector region having a first portion and a second portion around the first portion is covered with an insulating film and a polysilicon layer is formed on the insulating film, the polysilicon layer having an opening. The insulating film is then selectively removed about an area that is larger than the area of the opening to thereby expose the first and second portions of the collector region and form a gap between a part of the polysilicon layer and the second portion of the collector region. The gap is then filled with a silicon layer and impurities are doped to form an intrinsic base region in the first portion, followed by forming a side wall space to make the opening smaller than the original area.

Abstract: A bipolar transistor (10) includes a collector region (13), a base region (14) in the collector region (13), and an emitter region (20) in the base region (14). A portion (18) of an electrical conductor (16) is located over a base width (23) of the bipolar transistor (10). The emitter region (20) is self-aligned to the portion (18) of the electrical conductor (16) and is preferably diffused into the base region (14) in order to decrease the base width (23) without relying on extremely precise alignment between base region (14) and the portion (18) of the electrical conductor (16). The portion (18) of the electrical conductor (16) is used to deplete a portion of the base width (23) of the bipolar transistor (10).

Abstract: A semiconductor device and a manufacturing method therefor which can simultaneously realize both a reduction in base transit time by a reduction in base width and a reduction in base resistance by a reduction in link base resistance. The semiconductor device is manufactured by the method including the steps of forming a first impurity diffused layer of a first conduction type in a semiconductor substrate; forming a conducting film connected to the first impurity diffused layer; forming a first insulating film on the conducting film; forming a first hole through a laminated film composed of the first insulating film and the conducting film; forming a second impurity diffused layer of the first conduction type in the semiconductor substrate exposed to the first hole; forming a side wall from a second insulating film in the first hole to form a second hole; and forming a third impurity diffused layer of the first conduction type in the semiconductor substrate exposed to the second hole.

Abstract: Spacers are formed on the inside walls of a narrow silicon loss trench of a poly-emitter type bipolar transistor structure so that at most a narrow strip on the bottom of the trench receives high concentration doping when an extrinsic base region of the bipolar transistor is being doped. The narrowness of the exposed silicon surface which is etched to form the silicon loss trench slows vertical etching and thereby facilitates the formation of a shallow trench. The narrowness of the strip on the bottom of the trench which receives high concentration doping causes slow vertical diffusion of dopants. As a result, the highly doped link region which extends downward from the bottom of the trench does not extend downward much farther than the base region. A high cutoff frequency is therefore achievable by reducing the distance between the bottom of the base region and the top of the buried layer without decreasing the base-to-collector breakdown voltage.

Abstract: A bipolar device having a level difference between the contact area level of a base electrode and a base region in a silicon substrate, and the contact area level of an emitter electrode and an emitter region in the silicon substrate in the range of 0.03 .mu.m to 0.1 .mu.m by removing undesirable impurities from the emitter region and a predetermined horizontal distance between a sidewall and a device isolation film does not generate dislocation and show good electric characteristics.

Abstract: In fabricating a bipolar transistor, semiconductor dopant is introduced into a semiconductor body during a base doping operation to define a doped region, part of which constitutes a base region for the transistor. The base doping operation entails ion implanting the dopant into the body at a tilt angle of at least 15.degree. relative to the vertical. The minimum lateral base thickness and, when the base region abuts a slanted sidewall of a field insulating region, the minimum sidewall base thickness increase relative to the minimum vertical base thickness. As a result, the magnitude of the collector-to-emitter breakdown voltage typically increases. The minimum lateral, sidewall, and vertical base thicknesses vary with the tilt angle and base-implant energy in such a manner that the minimum lateral base thickness and the minimum sidewall base thickness are separately controllable from the minimum vertical base thickness.

Abstract: A low-noise PNP transistor comprising a cutoff region laterally surrounding the emitter region in the surface portion of the transistor. The cutoff region has such a conductivity is to practically turn off the surface portion of the transistor, so that the transistor operates mainly in the bulk portion. The cutoff region is formed by an N.sup.+ -type enriched base region arranged between the emitter region and the collector region.

Abstract: In a process for manufacturing a bipolar transistor, an intrinsic base is formed by a selective epitaxial growth while the lower surface of a base electrode single crystal silicon film 33 and the surface of a collector epitaxial layer 3 are exposed. In this process, the intrinsic base 8 and an extrinsic base 34 are grown as a single crystal to form a self-alignment type bipolar transistor having a reduced parasitic capacitance between the base and the collector.

Abstract: A bipolar transistor (100) and a method for forming the same. A base-link diffusion source layer (118) is formed over a portion of the collector region (102). The base-link diffusion source layer (118) comprises a material that is capable of being used as a dopant source and is capable of being etched selectively with respect to silicon. A barrier layer (119) is formed over the base-link diffusion source layer (118).A base electrode (114) is formed over at least one end portion of the barrier layer (119) and base-link diffusion source layer (118) and the exposed portions of the barrier layer (119) and underlying base-link diffusion source layer (118) are removed. An extrinsic base region (110) is diffused from the base electrode (114) and a base link-up region (112) is diffused from the base-link diffusion source layer (118). Processing may then continue to fore an intrinsic base region (108), emitter region (126), and emitter electrode (124).

Abstract: A superhigh speed vertical transistor having an ultra thin base, a vertical NPN transistor having a reverse direction structure for composing an IIL, and a lateral PNP transistor similarly composing an IIL to be an injector are formed on a P-type silicon substrate 1 by self-aligned and integrated. The emitter leading-out part opening of the superhigh speed vertical NPN transistor and the collector leading-out part opening of the vertical NPN transistor having a reverse direction structure are self-aligned to the base leading-out electrode. In the epitaxial layer, the P-type intrinsic base layer of superhigh speed vertical NPN transistor is formed by impurity diffusion from the emitter leading-out electrode formed of polysilicon film, and the P-type base layer of the vertical NPN transistor having a reverse direction structure is formed by ion implantation.

Abstract: A special two-dimensional intrinsic base doping profile is utilized to improve the output current-voltage characteristics of a vertical bipolar transistor whose intrinsic base includes a main intrinsic portion. The special doping profile is achieved with a pair of more lightly doped base portions that encroach substantially into the intrinsic base below the main intrinsic base portion. The two deep encroaching base portions extend sufficiently close to each other to set up a two-dimensional charge-sharing mechanism that typically raises the magnitude of the punch-through voltage. The transistor's current-voltage characteristics are thereby enhanced. Manufacture of the transistor entails introducing suitable dopants into a semiconductor body. In one fabrication process, a fast-diffusing dopant is employed in forming the deep encroaching base portions without significantly affecting earlier-created transistor regions.

Abstract: In a bipolar junction transistor of an epitaxial planar type comprising a base region, an emitter region formed in the base region, and a poly-silicon layer as an emitter poly-silicon electrode layer overlying the emitter region, the poly-silicon layer being used as an impurity diffusion source for forming the emitter region in fabrication of the transistor, the emitter poly-silicon electrode layer comprises a poly-silicon film containing an additive of one of C, O, and P overlying the emitter region and a poly-silicon layer overlying the poly-silicon film. An impurity is doped in the poly-silicon layer and is diffused into the base region through the poly-silicon film to form the emitter region in the base region in fabrication of the transistor. The poly-silicon film contains the additive and serves to prevent the poly-silicon film and the poly-silicon layer from grain growth which badly affects the impurity diffusion for forming the emitter region.

Abstract: A bipolar control transistor, forming part of an integrated current-limiter device comprises inside an epitaxial layer superimposed over a semiconductor substrate of a first type of conductivity, a base region of a second type of conductivity accessible from a base contact and regions of collector and emitter of the first type of conductivity contained in the base region and accessible from respective collector and emitter contacts. The base region comprises at least one highly-doped deep-body region which contains almost completely said emitter region, a lightly-doped body region which contains the collector region and an intermediate-doped region which co-operates with the first deep-body region to completely contain the emitter region and a surface area of the base region that is included between the regions of collector and emitter.

Abstract: A SiGe-HBT structure for device integration on thin-SOI substrates is disclosed. The emitter and base regions are vertical while the collector contact is lateral in the otherwise MOS-like device structure. This allows one to integrate a SiGe base, the device capacitances are reduced, and the transistor can be combined with fully-depleted CMOS in a SOI-BiCMOS technology.

Abstract: In a bipolar or BiCMOS process, a heavily doped buried layer of a first conductivity type and a heavily doped channel stop region of a second conductivity type are formed in a lightly doped substrate of the second conductivity type. A lightly doped epitaxial layer of the first conductivity type is grown. An implant of the first conductivity type creates a guard ring around the bipolar transistor active region and also creates a higher-doped collector region inside the active region. In the BiCMOS process, during the formation of CMOS wells, a silicon nitride mask over the bipolar transistor inhibits oxidation of the epitaxial layer and the oxidation-enhanced diffusion of the buried layer. As a result, the epitaxial layer can be made thinner, reducing the collector resistance. The MOS transistor wells can be formed without an underlying buried layer, simplifying the process and decoupling the bipolar and MOS transistor characteristics from each other.

Abstract: In a method of manufacturing a bipolar transistor, an oxide film pattern is formed on an epitaxial collector layer of a first conductive type which is formed on a buried layer of the first conductive type. A selectively-ion-implanted-collector (SIC) region is then formed in the collector layer, and after that, a base layer is grown on the SIC region with an inversely graded impurity distribution profile.

Abstract: There is described a bipolar power transistor with high breakdown voltage, obtained in a heavily doped semiconductor substrate of the N type, over which a lightly doped N type layer, constituting a collector region of the transistor, is superimposed. The transistor has a base region comprising a heavily doped P type diffusion, which extends into the lightly doped N type layer from a top surface. The transistor further includes an emitter region constituted by a heavily doped N type diffusion extending from the top surface within said heavily doped P type diffusion. The heavily doped P type diffusion is obtained within a deep lightly doped P type diffusion, extending from said top surface into the lightly doped N type layer and formed with acceptor impurities of aluminum atoms.

Abstract: A process for fabricating a BJT device on a semiconductor substrate is disclosed. The substrate serves as the collector. The process comprises the steps of, first, forming a shielding layer over the designated location over the surface of the substrate for defining the active region. The process further utilizes the shielding layer as the shielding mask for implanting impurities of into the substrate for forming an doped region. Then, a first field oxide layer is formed over the doped region and then removed. Sidewall spacers for the shielding layer are then formed. The process then utilizes the shielding layer and the sidewall spacers as the shielding mask for implanting impurities into portions of the doped region, forming a heavily-doped region, and the remaining portion of the doped region defines the base region. A second field oxide layer is then formed over the heavily-doped region. The sidewall spacers are then removed to form trenches in the places of the sidewall spacers.

Abstract: A bipolar transistor (100) and a method for forming the same. A diffusion source dielectric layer (118) is deposited over a semiconductor body (101). An emitter window (116) is then etched through the diffusion source dielectric layer (118). An extrinsic base region (110) is diffused from the diffusion source dielectric layer (118). The intrinsic base region (108) is then implanted. Base-emitter spacers (120) are then formed followed by the emitter electrode (124) and emitter region (126). The extrinsic base region (110) is self-aligned to the emitter eliminating the alignment tolerances for the lateral diffusion of the extrinsic base implant and an extrinsic base implant.

Abstract: A method for fabricating a super self-aligned bipolar junction transistor which reduces or eliminates emitter defects caused during critical etching steps by providing a non-critically thick dielectric etch stop (protection) layer (116) during all potentially damaging etching steps. An oxide or other dielectric layer (116, 130), is provided above the emitter region (152) of the semiconductor surface (110) during potentially damaging etching steps, such as dry etch procedures used to form critical device structures such as emitter opening 124 and sidewall spacers 146. Non-damaging etching procedures, such as wet etching, are used to remove dielectric protection layers (116, 130) to form less critical device structures, and/or form intermediate layer openings without damaging the silicon surface in the emitter (152), or other critical regions.

Abstract: A method of manufacturing a bipolar transistor including the steps of doping an impurity of the one conductivity type in a major surface portion of the semiconductor substrate to form a buried layer of the one conductivity type and growing an epitaxial layer on an entire surface on a major surface of the semiconductor substrate, forming a diffusion region of the opposite conductivity type in an emitter formation region on the major surface of the semiconductor substrate and forming a base connecting region in a base formation region to be in contact with the diffusion region of the opposite conductivity type, forming an insulating interlayer on the major surface of the semiconductor substrate including the diffusion region of the opposite conductivity type and the base connecting region, forming an emitter electrode layer contact hole reaching the diffusion region of the opposite conductivity type in an emitter formation region of the insulating interlayer and forming a collector region hole reaching the epit

Abstract: A self-aligned single polysilicon bipolar transistor structure and a method of formation thereof are provided. The transistor has an emitter structure characterised by T shape defined by inwardly extending sidewall spacers formed by oxidation of amorphous or polycrystalline silicon, rather than the conventional oxide deposition and anisotropic etch back. Advantageously the method compatible with bipolar CMOS processing and provides a single polysilicon self-aligned bipolar transistor with a reduced number of processing steps. Further the formation of inwardly extending sidewalls defining the emitter width reduces the emitter base junction width significantly from the minimum dimension which is defined by photolithography, while a large area emitter contact is also provided.

Abstract: A collector-up bipolar transistor having an undercut region (522) beneath extrinsic regions of a base layer (510) and an emitter layer (508). The extrinsic emitter region is depleted of charge carriers and provides passivation for the extrinsic portion of the base layer (508). Contact to the emitter layer may be made by forming contacts on the top surface of the substrate (500) or in a recess in the backside of the substrate.

Abstract: Disclosed is a pillar bipolar transistor which has a bidirectional operation characteristic and in which a parasitic junction capacitance of a base electrode, and a method for fabricating the transistor comprises etching a substrate using a first patterned insulating layer as a mask to form first and second pillarss separated by a trench therein; injecting an impurity using a mask to form a collector under the first and second pillars and in the second pillar; depositing a first oxide layer and a first polysilicon layer thereon; polishing the first polysilicon layer using the first oxide layer as a polishing stopper; removing a portion of the first polysilicon layer and a portion of the first oxide layer to define an extrinsic base; etching the oxide layer formed on both sides of the first pillar to a predetermined depth to define a connecting portion and forming a buried polysilicon therein to form the connecting portion; depositing a second oxide layer and a second polysilicon layer thereon; polishing the s