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: A method of manufacturing an electronic device including a PNP bipolar transistor comprises forming a collector in a substrate, depositing a base layer and an emitter layer on the substrate, and growing a nitride interface layer on the base layer as a base current modulation means, such that the nitride interface layer is arranged between the base layer and the emitter layer.

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: 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: 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: In a method of fabricating an integrated silicon-germanium heterobipolar transistor a silicon dioxide layer arranged between a silicon-germanium base layer and a silicon emitter layer is formed by means of Rapid Thermal Processing (RTP) to ensure enhanced component properties of the integrated silicon-germanium heterobipolar transistor.

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: 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: In a method of fabricating an integrated silicon-germanium heterobipolar transistor a silicon dioxide layer arranged between a silicon-germanium base layer and a silicon emitter layer is formed by means of Rapid Thermal Processing (RTP) to ensure enhanced component properties of the integrated silicon-germanium heterobipolar transistor.

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. 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. 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: 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).