Abstract: An integrated stacked capacitor comprises a first capacitor film (46) of polycrystalline silicide (poly), a second capacitor film (48) and a first dielectric (26) sandwiched between the first capacitor film (46) and second capacitor film (48). A second dielectric (34) and a third capacitor film (50) are provided. The second dielectric (34) is sandwiched between the second capacitor film (48) and third capacitor film (50). A method for fabrication of an integrated stacked capacitor comprises the following sequence of steps: applying a polysilicide layer (20) to form the first capacitor film (46); applying a first dielectric (26); applying a first metallization layer (28) to form the second capacitor film (48); applying a second dielectric (34); and applying a second metallization layer (34) to form the third capacitor film (50).

Abstract: A method for manufacturing a semiconductor device includes forming a buried layer of a semiconductor substrate. An active region is formed adjacent at least a portion of the buried layer. A first isolation structure is formed adjacent at least a portion of the buried layer. A second isolation structure is formed adjacent at least a portion of the active region. A base layer is formed adjacent at least a portion of the active region. A dielectric layer is formed adjacent at least a portion of the base layer, and then at least part of the dielectric layer is removed at an emitter contact location and at a sinker contact location. An emitter structure is formed at the emitter contact location. Forming the emitter structure includes etching the semiconductor device at the sinker contact location to form a sinker contact region. The sinker contact region has a first depth. The method may also include forming a gate structure.

Abstract: The present invention is a method for forming super steep doping profiles in MOS transistor structures. The method comprises forming a carbon containing layer (110) beneath the gate dielectric (50) and source and drain regions (80) of a MOS transistor. The carbon containing layer (110) will prevent the diffusion of dopants into the region (40) directly beneath the gate dielectric layer (50).

Abstract: The present invention is a method for forming super steep doping profiles in MOS transistor structures. The method comprises forming a carbon containing layer (110) beneath the gate dielectric (50) and source and drain regions (80) of a MOS transistor. The carbon containing layer (110) will prevent the diffusion of dopants into the region (40) directly beneath the gate dielectric layer (50).

Abstract: The present invention is a method for forming super steep doping profiles in MOS transistor structures. The method comprises forming a carbon containing layer (110) beneath the gate dielectric (50) and source and drain regions (80) of a MOS transistor. The carbon containing layer (110) will prevent the diffusion of dopants into the region (40) directly beneath the gate dielectric layer (50).

Abstract: An integrated circuit programmable structure (60) is formed for use a trim resistor and/or a programmable fuse. The programmable structure comprises placing heating elements (70) in close proximity to the programmable structure (60) to heat the programmable structure (60) during programming.

Abstract: An integrated circuit and method of fabricating the integrated circuit is disclosed. The integrated circuit includes vertical bipolar transistors (30, 50, 60), each having a buried collector region (26?). A carbon-bearing diffusion barrier (28c) is disposed over the buried collector region (26?), to inhibit the diffusion of dopant from the buried collector region (26?) into the overlying epitaxial layer (28). The diffusion barrier (28c) may be formed by incorporating a carbon source into the epitaxial formation of the overlying layer (28), or by ion implantation. In the case of ion implantation of carbon or SiGeC, masks (52, 62) may be used to define the locations of the buried collector regions (26?) that are to receive the carbon; for example, portions underlying eventual collector contacts (33, 44c) may be masked from the carbon implant so that dopant from the buried collector region (26?) can diffuse upward to meet the contact (33).

Abstract: An integrated circuit programmable structure (60) is formed for use a trim resistor and/or a programmable fuse. The programmable structure comprises placing heating elements (70) in close proximity to the programmable structure (60) to heat the programmable structure (60) during programming.

Abstract: A heterojunction bipolar transistor (30) in a silicon-on-insulator (SOI) structure is disclosed. The transistor collector (28), heterojunction base region (20), and intrinsic emitter region (25) are formed in the thin film silicon layer (6) overlying the buried insulator layer (4). A base electrode (10) is formed of polysilicon, and has a polysilicon filament (10f) that extends over the edge of an insulator layer (8) to contact the silicon layer (6). After formation of insulator filaments (12) along the edges of the base electrode (10) and insulator layer (8), the thin film silicon layer (6) is etched through, exposing an edge. An angled ion implantation then implants the heterojunction species, for example germanium and carbon, into the exposed edge of the thin film silicon layer (6), which after anneal forms the heterojunction base region (20).

Abstract: A semiconductor device (100) and a method for constructing a semiconductor device (100) are disclosed. A trench isolation structure (112) and an active region (110) are formed proximate an outer surface of a semiconductor layer (108). An epitaxial layer (111) is deposited outwardly from the trench isolation structure (112). A first insulator layer (116) and a second insulator layer (118) are grown proximate to the epitaxial layer (111). A gate stack (123) that includes portions of the first insulator layer (116 and the second insulator layer (118) is formed outwardly from the epitaxial layer (111). The gate stack (123) also includes a gate (122) with a narrow region (130) and a wide region (132) formed proximate the second insulator layer (118. The epitaxial layer (111) is heated to a temperature sufficient to allow for the epitaxial layer (111) to form a source/drain implant region (126) in the active region (110).

Abstract: An improved BJT is described that maximizes both Bvceo and Ft/Fmax for optimum performance. Scattering centers are introduced in the collector region (80) of the BJT to improve Bvceo. The inclusion of the scattering centers allows the width of the collector region WCD (90) to be reduced leading to an improvement in Ft/Fmax.

Abstract: A method of fabricating an epitaxial silicon-germanium layer for an integrated semiconductor device comprises the step of depositing an arsenic in-situ doped silicon-germanium layer, wherein arsenic and germanium are introduced subsequently into different regions of said silicon-germanium layer during deposition of said silicon-germanium layer. By separating arsenic from germanium any interaction between arsenic and germanium is avoided during deposition thereby allowing fabricating silicon-germanium layers with reproducible doping profiles.

Abstract: A method for manufacturing a semiconductor device includes forming a buried layer of a semiconductor substrate. An active region is formed adjacent at least a portion of the buried layer. A first isolation structure is formed adjacent at least a portion of the buried layer. A second isolation structure is formed adjacent at least a portion of the active region. A base layer is formed adjacent at least a portion of the active region. A dielectric layer is formed adjacent at least a portion of the base layer, and then at least part of the dielectric layer is removed at an emitter contact location and at a sinker contact location. An emitter structure is formed at the emitter contact location. Forming the emitter structure includes etching the semiconductor device at the sinker contact location to form a sinker contact region. The sinker contact region has a first depth. The method may also include forming a gate structure.

Abstract: An integrated stacked capacitor comprises a first capacitor film (46) of polycrystalline silicide (poly), a second capacitor film (48) and a first dielectric (26) sandwiched between the first capacitor film (46) and second capacitor film (48). A second dielectric (34) and a third capacitor film (50) are provided. The second dielectric (34) is sandwiched between the second capacitor film (48) and third capacitor film (50). A method for fabrication of an integrated stacked capacitor comprises the following sequence of steps: applying a polysilicide layer (20) to form the first capacitor film (46); applying a first dielectric (26); applying a first metallization layer (28) to form the second capacitor film (48); applying a second dielectric (34); and applying a second metallization layer (34) to form the third capacitor film (50).

Abstract: High-voltage bipolar transistors (30, 60) in silicon-on-insulator (SOI) integrated circuits are disclosed. In one disclosed embodiment, an collector region (28) is formed in epitaxial silicon (24, 25) disposed over a buried insulator layer (22). A base region (32) and emitter (36) are disposed over the collector region (28). Buried collector region (31) are disposed in the epitaxial silicon (24) away from the base region (32). The transistor may be arranged in a rectangular fashion, as conventional, or alternatively by forming an annular buried collector region (31). According to another disclosed embodiment, a high voltage transistor (60) includes a central isolation structure (62), so that the base region (65) and emitter region (66) are ring-shaped to provide improved performance. A process for fabricating the high voltage transistor (30, 60) simultaneously with a high performance transistor (40) is also disclosed.

Abstract: High-voltage bipolar transistors (30, 60) in silicon-on-insulator (SOI) integrated circuits are disclosed. In one disclosed embodiment, an collector region (28) is formed in epitaxial silicon (24, 25) disposed over a buried insulator layer (22). A base region (32) and emitter (36) are disposed over the collector region (28). Buried collector region (31) are disposed in the epitaxial silicon (24) away from the base region (32). The transistor may be arranged in a rectangular fashion, as conventional, or alternatively by forming an annular buried collector region (31). According to another disclosed embodiment, a high voltage transistor (60) includes a central isolation structure (62), so that the base region (65) and emitter region (66) are ring-shaped to provide improved performance. A process for fabricating the high voltage transistor (30, 60) simultaneously with a high performance transistor (40) is also disclosed.

Abstract: A method for manufacturing a semiconductor device includes forming a buried layer of a semiconductor substrate. An active region is formed adjacent at least a portion of the buried layer. At least part of the active region is removed to form a shallow trench opening. A dielectric layer is formed proximate the active region at least partially within the shallow trench opening. At least part of the dielectric layer is removed to form a collector contact region. A collector contact may be formed at the collector contact region. The collector contact may be operable to electrically contact the buried layer.

Abstract: A method for manufacturing a semiconductor device includes forming a buried layer of a semiconductor substrate. An active region is formed adjacent at least a portion of the buried layer. A first isolation structure is formed adjacent at least a portion of the buried layer. A second isolation structure is formed adjacent at least a portion of the active region. A base layer is formed adjacent at least a portion of the active region. A dielectric layer is formed adjacent at least a portion of the base layer, and then at least part of the dielectric layer is removed at an emitter contact location and at a sinker contact location. An emitter structure is formed at the emitter contact location. Forming the emitter structure includes etching the semiconductor device at the sinker contact location to form a sinker contact region. The sinker contact region has a first depth. The method may also include forming a gate structure.

Abstract: A heterojunction bipolar transistor (30) in a silicon-on-insulator (SOI) structure is disclosed. The transistor collector (28), heterojunction base region (20), and intrinsic emitter region (25) are formed in the thin film silicon layer (6) overlying the buried insulator layer (4). A base electrode (10) is formed of polysilicon, and has a polysilicon filament (10f) that extends over the edge of an insulator layer (8) to contact the silicon layer (6). After formation of insulator filaments (12) along the edges of the base electrode (10) and insulator layer (8), the thin film silicon layer (6) is etched through, exposing an edge. An angled ion implantation then implants the heterojunction species, for example germanium and carbon, into the exposed edge of the thin film silicon layer (6), which after anneal forms the heterojunction base region (20).

Abstract: A heterojunction bipolar transistor (30) in a silicon-on-insulator (SOI) structure is disclosed. The transistor collector (28), heterojunction base region (20), and intrinsic emitter region (25) are formed in the thin film silicon layer (6) overlying the buried insulator layer (4). A base electrode (10) is formed of polysilicon, and has a polysilicon filament (10f) that extends over the edge of an insulator layer (8) to contact the silicon layer (6). After formation of insulator filaments (12) along the edges of the base electrode (10) and insulator layer (8), the thin film silicon layer (6) is etched through, exposing an edge. An angled ion implantation then implants the heterojunction species, for example germanium and carbon, into the exposed edge of the thin film silicon layer (6), which after anneal forms the heterojunction base region (20).