Abstract: A method of producing the bipolar transistor includes forming an aperture through a triple layer over an active region of an epitaxial layer, then forming a shallow polysilicon film at the bottom of the aperture. An intrinsic base region is formed by segregating a conductive impurity to the epitaxial layer by thermally oxidizing the polysilicon film. Then an extrinsic base region is formed by diffusing impurities into the epitaxial layer from a polysilicon sidewall formed on the aperture. In the transistor fabricated according to this method, an insulation layer of oxide silicon or nitrogen silicon is formed under the base polysilicon layer. Accordingly, impurities from the base polysilicon layer do not diffuse into the epitaxial layer during the diffusion process. Instead, the extrinsic base region is formed by the diffusion of impurities from the polysilicon sidewall which is connected to the base polysilicon layer. Therefore the length of the entire base region is shortened.

Abstract: A bipolar transistor is shown having a collector of one conductivity type, a base of an opposite conductivity type, and an emitter of the one conductivity type, which are formed in a semiconductor substrate. A major surface portion of the substrate is doped with an impurity of the one conductivity type to form a buried layer of the one conductivity type. An epitaxial layer is grown on an entire surface of a major surface portion of the substrate. A diffusion region of the opposite conductivity type is formed in an emitter formation region on a major surface portion of the substrate with the diffusion region serving as an intrinsic base region. An insulating interlayer is formed on the major surface portion of the substrate and covers the intrinsic base region. Portions of the insulating interlayer define an emitter electrode layer contact hole that reaches the diffusion region at an emitter region.

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 base electrode (114) is formed over at least one end portion of the base-link diffusion source layer (118) and the exposed portions of the 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 form an intrinsic base region (108), emitter region (126), and emitter electrode (124).

Abstract: A semiconductor device with a bipolar transistor formed in a layer of semiconductor material (2) provided on an insulating substrate (1), in which material a collector zone (4), a base zone (5), and an emitter zone (6) are provided below a strip of insulating material (3) situated on the layer (2), which zones are connected to contact regions (7, 8, 9, 10) lying adjacent the strip (3), three of the contact regions (8, 9, 10) lying next to one another at a same side of the strip (3), of which two (8 and 9) are connected to the base zone (5) while the third (10), which lies between the former two (8 and 9), is connected to the emitter zone (6). The three contact regions (8, 9, 10) situated next to another at the same side of the strip (3) are provided alternately in the layer of semiconductor material (2) and in a further layer of semiconductor material (19) extending up to the strip (3).

Abstract: A buried layer contact for a integrated circuit structure is provided, with particular application for a contact for a buried collector of a bipolar transistor. The buried layer contact takes the form of a sinker comprising a fully recessed trench isolated structure having dielectric lined sidewalls and filled with conductive material, e.g. doped polysilicon which contacts the buried layer. The trench isolated contact is more compact than a conventional diffused sinker structure, and thus beneficially allows for reduced transistor area. Advantageously, a reduced area sinker reduces the parasitic capacitance and power dissipation. In a practical implementation, the structure provides for an annular collector contact structure to reduce collector resistance.

Abstract: A semiconductor device comprises a semiconductor substrate having a main surface, a first semiconductor region of a first conductive type, formed on the main surface of the semiconductor substrate, a surrounding of the first semiconductor region is buried with a first insulation film, a second semiconductor region of a second conductive type, formed on the first insulation film and the first semiconductor region, a second insulation film, formed on the second semiconductor region, an end portion of the second insulation film is positioned above the first insulation film, and having an opening at a central portion thereof to be positioned above the first semiconductor region, and a third semiconductor region of a first conductivity type formed on a surface of the second semiconductor region exposed through the opening of the second insulation film.

Abstract: The upper and lateral surfaces of a polycide electrode comprising a P.sup.+ -type polycrystalline silicon layer 6 and a tungsten silicide layer 13 are covered with silicon nitride films 9, 9A. Reduction of the boron concentration at the interface between the lower polycrystalline silicon layer and the upper tungsten silicide layer is suppressed.

Abstract: A hetero-junction bipolar transistor having an emitter composed of a semiconductor having a wider forbidden band width than that of a semiconductor constituting a base is disclosed. In the transistor, the emitter and the electrode leader area composed of a single crystalline semiconductor are provided being extended from the upper part of the emitter to the surface of the base through an insulating layer, for the purpose of making it possible to miniaturize the transistor and to operate the transistor at a high-speed by decreasing the emitter resistance.

Abstract: An n type collector region is formed at a main surface of a p type silicon substrate. A p type base region is formed at a surface of the collector region. An n type emitter region is formed at a surface of the base region. A polycrystalline silicon layer is formed on a surface of the emitter region. An interlayer insulation layer is formed so as to cover the polycrystalline silicon layer. A contact hole is formed on the emitter region through the interlayer insulation layer and the polycrystalline silicon layer and reaching the surface of the emitter region. A metal electrode is formed within contact hole so as to provide contact with the surface of the emitter region. According to this structure, the emitter resistance can be reduced. Thus, the operation speed of a bipolar transistor can be improved.

Abstract: A BiCMOS manufacturing process for fabricating an emitter of a bipolar transistor includes the steps of forming footings on a silicon substrate for prospectively bearing edges of the emitter, forming a polysilicon emitter having a medial portion overlying the silicon substrate and lateral edges on the footings, removing the footings leaving notches at the lateral edges of the polysilicon emitter and refilling the notches with a thin polysilicon film. The bipolar transistor in a BiCMOS integrated circuit resulting from this process includes a silicon semiconductor substrate having a substantially flat surface, a field oxide film laterally bounding the silicon semiconductor substrate and a polysilicon emitter abutting the flat surface of the silicon semiconductor substrate.

Abstract: A bipolar transistor (100) and a method for forming the same. A base electrode (114) is separated from the collector region (102) by an insulator layer (110). A doped conductive spacer (115) is formed laterally adjacent the base electrode (114). The conductive spacer (115) comprises a conductive material that is capable of serving as a dopant source for n and p-type dopants and is able to be selectively etched with respect to silicon (e.g., silicon-germanium). Base link-up region (112) is diffused from conductive spacer (115) into the collector region (102). Processing then continues to form an intrinsic base region (108), emitter region (126), and emitter electrode (124).

Abstract: A bipolar transistor in accordance with the invention includes a polysilicon base contact (607A) which is self-aligned with a polysilicon emitter (303). The polysilicon emitter is formed from a first polysilicon layer overlying an intrinsic base region (502) in a substrate (201). An extrinsic base (504) in the substrate is in contact with the intrinsic base and is self-aligned with a spacer (406) adjacent to the emitter. The polysilicon base contact is formed from a second polysilicon layer (407) in contact with the extrinsic base and overlying the emitter. A second sidewall spacer (508) is formed on the second polysilicon layer on step caused by the emitter. A protective layer (509, 510) formed on portions of the second polysilicon layer protects the base contact when the second spacer and the underlying portion of the second polysilicon layer are removed.

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 said active area is implanted, said 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 lateral bipolar transistor and method of making the transistor are disclosed. The device is made by etching a trench around a central region of a semiconductor body. An emitter is buried beneath the surface of this central area and contact to it is made via a self-alignment technique. The collector region of the transistor is contacted through the floor of the trench while the base region of the transistor is contacted in a region that surrounds the trench. The described method is compatible with the simultaneous manufacture of FET devices on the same chip.

Abstract: A monolithic semiconductor device includes a field effect transistor and a bipolar junction transistor with an elevated emitter structure. An elevation structure raises the BJT emitter above the plane of the base. The elevation structure increases travel distance between a heavily doped base contact region and the emitter and protects against encroachment without increasing the total surface area allocated to the BJT device. A spacer oxide separates the polysilicon base contact and the elevation structure.

Abstract: A semiconductor device in which a bipolar transistor is provided, such as a BiCMOS, and a production process thereof. The device has collector region of a first conductivity type; an intrinsic base region of a second conductivity type provided on the collector region; a graft base provided on the periphery of this intrinsic base region; and an emitter region of the first conductivity type provided by self-alignment with respect to the intrinsic base. A base electrode is provided in the upper portion where the graft base is scheduled to be formed. A trench is provided by self-alignment along the end portion on the outer circumference side of this base electrode. The graft base is provided in contact with the inner circumference of this trench.

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: A bipolar transistor module which can be implemented into existing CMOS processes without the use of buried layers of epitaxy is described. The transistor makes use of a synthesis of new ideas to achieve high performance. Extended polysilicon electrodes (2,4,6) are utilised to reduce device dimensions and a compatible well is described which maintains a p-channel MOS transistor electrical characteristics whilst lowering the collector series resistance.

Abstract: In accordance with the invention, the emitter region of a BJT is formed prior to the formation of the base contact regions so that the base contact regions are not enlarged during a thermal cycle used to form the emitter and the base contact regions remain small. Preferably, the base contact regions are formed by ion implantation after the emitter is formed. In addition, the base interconnect links may be metal (or polycide) rather than polysilicon so that the base interconnect resistance is reduced.This results in the following advantages:(1) reduced emitter-base junction leakage(2) reduced collector-base junction capacitance.(3) reduced base interconnection series resistance.

Abstract: The invention relates to a method of making a monolithic integrated circuit with at least one CMOS field-effect transistor and one npn bipolar transistor wherein a thin oxide layer is covered with a protective polysilicon layer in both the bipolar-transistor area and the field-effect-transistor area.

Abstract: A semiconductor device includes an n-type low-resistance region (2) formed on a p-type monocrystalline semiconductor substrate (1), an n-type epitaxial layer (3) formed on the n-type low-resistance region (2), an insulating film (5) formed on the n-type epitaxial layer (3) and having a first opening selectively formed therein, and an n-type polysilicon film (8) having an overhung portion extending from the entire peripheral portion of the opening to the inside of the opening. An n-type polysilicon film (9) is formed downward from the bottom surface of the overhung portion, and a p-type monocrystalline silicon film (6) serving as a base is formed on the surface of the n-type epitaxial layer in the first opening. The base (6) is in contact with the n-type polysilicon films (8, 9), and the n-type emitter (10) is formed immediately below the n-type emitter polysilicon films (8, 9) to have an annular shape.

Abstract: A semiconductor device having a monocrystalline semiconductor layer, a first insulating film, a base leading electrode, and a second insulating film is arranged such that a predetermined pattern window is provided in the second insulating film, a third insulating film of silicon oxide is provided between two peripheries of the predetermined pattern window, a first window is provided between a side of the second insulating film and a side of the third insulating film, a second window extends from the first window and is larger than the first window so that the base leading electrode and the third insulating film have overhang portions, first spacers are provided respectively in alignment with the peripheries of the predetermined pattern window and in alignment with the sides of the third insulating film, second spacers cover the first spacers and the overhang portions, and emitter layers are provided between and in self-alignment with the second spacers.

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 semiconductor device (8) has an insulating layer (16) overlying a semiconductor substrate (12). The insulating layer has a first opening that defines an aperture (18) extending from the insulating layer to the semiconductor substrate, and at least a first portion of a first conductive terminal (42) is disposed in the aperture. A second conductive terminal (52) has a second portion (28) disposed in the aperture. The second portion of the second conductive terminal is separated from the first conductive terminal by a composite dielectric layer including a nitride layer (32) and an oxide layer (30). In one approach, the oxide layer is formed by the oxidation of the second portion of the second conductive terminal.

Abstract: A bipolar transistor is formed on a silicon substrate having a silicon oxide film. An n-silicon layer having a top surface of a (100) plane is formed on the silicon oxide film and is used as a collector layer. An end face constituted by a (111) plane is formed on the end portion of the collector layer by etching, using an aqueous KOH solution. A B-doped p-silicon layer is formed on the end face by epitaxial growth and is used as a base layer. Furthermore, an As-doped n-silicon layer is formed on the base layer and is used as an emitter layer. Electrodes are respectively connected to the collector, base, and emitter layers.

Abstract: A collector layer of a first electrically conductive type is surrounded by an oxide film for separating elements. A base layer comprising an epitaxial layer of a second electrically conductive type is formed on the collector layer. A polysilicon film of the second electrically conductive type is formed at a first area of a surface of the base layer. An emitter layer of the first electrically conductive type is formed at a second area of a surface of the base layer. A base polysilicon electrode comprising of the second electrically conductive type is formed on the polysilicon film and on the oxide film for separating elements. A sidewall comprising an insulating film is formed over a lateral wall of the base polysilicon electrode and a lateral wall of the polysilicon film. An emitter polysilicon electrode of the first electrically conductive type is formed over the emitter layer and the side wall.

Abstract: A transversal bipolar transistor is structured to have a single crystal semiconductor film provided on a single crystal semiconductor region which is provided on a semiconductor substrate. The semiconductor substrate is of a first conductivity type, and the single crystal semiconductor region is of a second conductivity type which is opposite to the first conductivity type. The single crystal semiconductor film is divided in the transversal direction into a central portion of the second conductivity type for a base region and left and right portions of the first conductivity type for emitter and collector regions. The transversal bipolar transistor may be integrated with a vertical bipolar transistor commonly on the semiconductor 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

Abstract: The invention provides a heterojunction bipolar transistor which has a low reistance SiGe base and is high in current gain and cutoff frequency even at low temperatures near the liquid nitrogen temperature. The transistor fabrication process comprises forming an n-type collector layer on a silicon substrate and a dielectric film on the collector layer, forming a base electrode of p.sup.+ -type polysilicon having an opening on the dielectric film, isotropically etching the dielectric film on the collector layer by using the opening of the base electrode to form a window, forming an external base layer of p.sup.+ -type silicon on the collector layer exposed by the window, selectively etching the external base layer to form an aperture in a central region, forming a p-type SiGe intrinsic base layer in the aperture of the external base layer and then forming an n.sup.+ -type emitter on the intrinsic base layer.

Abstract: A method of fabricating BiCMOS devices, and the resultant BiCMOS device, are disclosed. According to the present invention, over-etching to the substrate on the deposited polysilicon emitter is prevented by providing additional oxide beneath a polysilicon layer as an etch stop. Despite inclusion of an oxide to define an end-point during patterning of an emitter, fabrication complexity is reduced by avoiding additional SAT masking and oxidation steps.

Abstract: Vertically stacked regions of n-type and p-type conductivity are formed around bipolar and field effect transistors to reduce parasitic capacitance between the semiconductor device and surrounding well regions. Under reverse bias a portion of the vertically stacked region is fully depleted and thus reduces the parasitic capacitance between the semiconductor device and the well region.

Abstract: A ring-shaped emitter region is formed either in a region a little toward an inner periphery or in a region a little toward an outer periphery in an upper layer portion of a ring-shaped base region of a bipolar transistor. A conductive layer is laminated through an insulating layer in a region surrounded by the ring-shaped emitter region provided a little toward the inner periphery of the base region, a conductive side wall is formed on the sides of the conductive layer and the insulating layer, and the ring-shaped emitter region and the conductive layer are connected through the conductive side wall. A metallic emitter electrode is connected to the conductive layer.

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 form an intrinsic base region (108), emitter region (126), and emitter electrode (124).

Abstract: A bipolar transistor with a structure such that it is possible to reduce the parasitic capacity without sacrificing improvements in cut-off frequency f.sub.T, in which a P.sup.+ -type polycrystalline silicon film 122A is provided on the side wall of an opening 143A which is provided in a silicon nitride film 152A serving as the middle layer of a laminated insulation film 107A, and, a P-type single crystal silicon layer 121A constituting the intrinsic base region is connected to a P.sup.+ -type polycrystalline silicon film 111 which is a base drawing electrode via a thin P.sup.+ -type polycrystalline silicon film 123A.

Abstract: A bipolar lateral device is disclosed having a high BV.sub.ceo. The device is formed according to a single polysilicon process. In one embodiment silicide is excluded from the surface of the N+ doped polysilicon protecting the N- base width region of the device and the resulting device has a BV.sub.ceo of 8 to 10 V. In another embodiment, the silicide is excluded from the surface of the polysilicon protecting the n-base width region and the polysilicon is maintained as intrinsic polysilicon. The resulting device has a BV.sub.ceo of about 20 V. The devices are useful as voltage clamping devices in programmable logic circuits which must withstand a collector to emitter reverse bias voltage that is sufficient to program either vertical fuse or lateral fuse devices.

Abstract: A bipolar integrated circuit with N-type wells (2) formed in a P-type substrate (1) includes in first wells, first transistors (EBC), the well of which constitutes the collector. P-type base region (7a) is formed in the first well with an N+ emitter region (8) formed in the base region. In at least a second well forming a collector, a composite second transistor (E'B'C') is constituted by an elemental third transistor (E.sub.1 B.sub.1 C') comprising regions of the same doping level as the first transistor and an elemental fourth transistor (E.sub.2 B.sub.2 C') having a base region (11) with a high doping level with respect to that of the bases of the first transistor. Emitter regions (8b, 12) of the elemental transistors are of the same doping level as that of the first transistors. The emitters and bases of the third and fourth elementary transistors are interconnected and constitute the emitter and the base of the composite second transistor.

Abstract: Disclosed is a semiconductor device using a polycrystalline compound semiconductor with a low resistance as a low resistance layer, and its fabrication method. The above polycrystalline compound semiconductor layer is doped with C or Be as impurities in a large amount, and is extremely low in resistance. The polycrystalline compound semiconductor layer is formed by either of a molecular beam epitaxy method, an organometallic vapor phase epitaxy method and an organometallic molecular beam epitaxy method under the condition that a substrate temperature is 450.degree. C. or less and the ratio of partial pressure of a V-group element to a III-group element is 50 or more.

Abstract: A modification of the self-aligned double poly fabrication process for bipolar transistors employs a thin sacrificial dielectric film to protect the wafer surface during the etching of an emitter opening through an overlying polysilicon contact layer. The sacrificial layer, which is preferably silicon dioxide for a silicon wafer, is thick enough to serve as an etch stop but thin enough to permit dopant from the polysilicon contact to be driven-in through the film to form an extrinsic base region. The dielectric film is left in place under the base contact polysilicon, but removed from the emitter area. It is preferably about 10-20 Angstroms thick when implemented as a silicon dioxide film. With this material system, the extrinsic base drive-in is preferably performed either by a rapid isothermal anneal at about 1,000.degree. C. for about 30-40 seconds, or in a furnace at about 975.degree. C. for about 10 minutes.

Abstract: The invention is a semiconductor device having a metal-semiconductor contact structure. The device includes a metal region having such a high conductivity as to serve as a contact plug. The device also includes a first semiconductor region having a first band gap and being so doped with one conductive type dopant as to exhibit a high conductivity. The device also includes a semiconductor film having a second band gap wider than the first band gap. The semiconductor film is in contact at its opposite surfaces with a part of the metal region and a part of the first semiconductor region respectively. The semiconductor film is doped with the one conductive type dopant so heavily as to suppress electrical current flow between the part of the metal region and the part of the first semiconductor region through the semiconductor film. The semiconductor film comprises amorphous silicon or poly-crystalline silicon.

Abstract: An n.sup.+ buried layer is formed on a surface of p.sup.- semiconductor substrate. An n.sup.- epitaxial growth layer and an n.sup.+ diffusion layer are formed on a surface of n.sup.+ buried layer. A p.sup.- base region and p.sup.+ external base region adjoining to each other are formed on a surface of n.sup.- epitaxial growth layer. An an n.sup.+ emitter region is formed at a surface of p.sup.- base region. An emitter electrode is formed adjacently to n.sup.+ emitter region. The emitter electrode is made of polycrystalline silicon doped with phosphorus at a concentration from 1.times.10.sup.20 cm.sup.-3 to 6.times.10.sup.20 cm.sup.-3.

Abstract: Bipolar transistors and MOS transistors on a single semiconductor substrate involves depositing a single layer of polysilicon on a substrate, including complementary transistors of either or both types, and a method for fabricating same. The devices are made by depositing a single layer of polysilicon on a substrate and etching narrow slots in the form of rings around every bipolar emitter area, which slots are thereafter filled with an insulating oxide. Then, emitters and extrinsic base regions are formed. The emitters are self-aligned to the extrinsic base regions. An optional cladding procedure produces a surface layer of a silicide compound, a low resistance conductor. The resulting structure yields a high-performance device in which the size constraints are at a minimum and contact regions may be made at the top surface of the device.

Abstract: In a semiconductor device, an emitter electrode has a polysilicon layer provided in a first contact hole and on a first insulating film. The polysilicon layer is in contact with an emitter region and is covered with a metal layer. A second contact hole is provided on a part of a second insulating film located on a substantially flat portion of the metal layer. A third contact hole is provided in those portions of the first insulating film and a second insulating layer which are located on a base region.

Abstract: A transistor is formed on a bonded SOI substrate. A collector electrode is connected to the peripheral sides of the collector areas on the insulator. A first insulator of isolation is formed on the peripheral side of the collector electrode. A base electrode is connected to a base area on the first insulator of isolation. Second insulators of isolation are formed on the peripheral side of a base electrode, and emitter electrode is connected to an emitter area by the second insulators of isolation. The connections between the collector electrode and the collector areas, between the base electrode and the base area, and between the emitter electrode and the emitter area are made under the emitter electrode, so the occupation area is small.

Abstract: A process is provided for forming a bipolar transistor and a structure thereof. In particular a single polysilicon self-aligned process for a bipolar transistor having a polysilicon emitter is provided. A sacrificial layer defining an opening is provided in a device well region of a substrate, and, after forming a self-aligned base region within the opening, emitter material is selectively provided in the opening to form an emitter-base junction. The sacrificial layer functions as a mask for ion implantations to form the base region, and if required, an underlying local collector region. The sacrificial layer is removed, to expose the well region adjacent sidewalls of the emitter structure. A self-aligned link region implant may be performed before forming isolation on exposed sidewalls of the emitter structure. Extrinsic base contacts are formed in the surface of the surrounding well region.

Abstract: A contact structure and a method for fabrication is disclosed for a semiconductor device that includes a plurality of semiconductor regions along the surface of the device, each region having a top surface and at least a sidewall surface, where a first part of the semiconductor regions are of a first conductivity type and a second part of semiconductor regions are of a second conductivity type. Select dielectric spacers are formed along the sidewalls of the select semiconductor regions of first conductivity type while a refractory metal such as titanium, molybdenum or tungsten is used to form contact on the sidewalls of the semiconductor regions of second conductivity type. This structure is most advantageous in bipolar, CMOS and BiCMOS transistor structures as it allows the formation of the sidewall spacers on emitter/gate contacts while having local metal interconnects with the reactive metal on the sidewall of the select base/source/drain contacts.

Abstract: In a bipolar device, selective epitaxial silicon provides an improved intrinsic-extrinsic base link. A trench physically separates an intrinsic and extrinsic base portion. The trench includes sidewalls having a thin oxide layer formed thereon. The bottom of the trench is exposed during processing. A shallow link between the intrinsic-extrinsic regions of a bipolar transistor base is formed by depositing a heavily boron doped layer of silicon on the exposed portion of the trench. During subsequent processing, including rapid thermal anneal, there is some boron out-diffusion which forms a shallow diffused intrinsic-extrinsic base link.

Abstract: A semiconductor device comprising a semiconductor substrate with a base region, a collector region and an emitter region in a lateral arrangement. The base region having a first conductivity type, and the collector and emitter regions having a second conductivity type. A first conductor layer is patterned over the substrate with a base contact portion, a collector contact portion and an emitter contact portion, with the base contact portion, the collector contact portion and the emitter contact portion contacting the base region, the collector region and the emitter region, respectively. A second conductor layer is patterned over a portion of the base region and is electrically coupled to the emitter contact portion, whereby the second conductor layer functions as an electrostatic shield for the base region.

Abstract: A bipolar transistor includes a substrate, an insulating layer formed on the substrate, and a semiconductor layer having a bottom surface and side surfaces surrounded by the insulating layer. The semiconductor layer includes a collector region formed in a first surface portion of the semiconductor layer, and a collector lead region having a concentration higher than that of the collector region. The collector read region includes a silicon single crystal layer formed in a second surface portion of the semiconductor layer, and a polysilicon layer having side surfaces surrounded by the silicon single crystal layer. A base region is formed on the collector region, and an emitter region is formed in the base region.

Abstract: A sidewall construction is utilized in the fabrication of semiconductor devices comprising planar type bipolar transistors wherein the width of the sidewall construction can be accuracy controlled which, in turn, controls accuracy the channel length of the base of the planar type bipolar transistors. This technique provides ways of preventing short circuiting between the formed transistor collector and emitter regions of the planar type bipolar transistors. The sidewall construction can also be employed in fabrication combination planar type bipolar/MIS type transistors resulting in higher density of these structures over the prior art laterally positioned structures.

Abstract: A double-layered structure of the base electrode corresponding to the emitter diffused-region 15 to be formed, which consists of the first and second conducting films 5, 6. This structure effects to prevent the surface of the silicon substrate in the emitter diffused-region to be formed from being etched away by the overetching for forming the base electrode, with much reduction of leakage current due to the consequent damage to the silicon-substrate surface in the emitter diffused-region to be formed, leading to improvement in transistor yield.