Abstract: Complementary metal-oxide-semiconductor (CMOS) integrated circuits with bipolar transistors and methods for fabrication are provided. A bipolar transistor may have a lightly-doped base region. To reduce the resistance associated with making electrical contact to the lightly-doped base region, a low-resistance current path into the base region may be provided. The low-resistance current path may be provided by a base conductor formed from heavily-doped epitaxial crystalline semiconductor. Metal-oxide-semiconductor (MOS) transistors with narrow gates may be formed on the same substrate as bipolar transistors. The MOS gates may be formed using a self-aligned process in which a patterned gate conductor layer serves as both an implantation mask and as a gate conductor. A base masking layer that is separate from the patterned gate conductor layer may be used as an implantation mask for defining the lightly-doped base region.

Abstract: An improved lateral bipolar junction transistor and a method of forming such a lateral bipolar transistor without added mask in CMOS flow on a p-substrate are disclosed. The CMOS flow includes patterning and n-well implants; pattern and implant pocket implants for core nMOS and MOS; pattern and implants pocket implants I/O nMOS and pMOS; sidewall deposit and etch and then source/drain pattern and implant for nMOS and pMOS. The bipolar transistor is formed by forming emitter and collector contacts by implants used in source/drain regions; forming an emitter by implants done in core pMOS during core pMOS LDD extender; and forming part of an base by pocket implant steps.

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

Abstract: A semiconductor device has: active regions including a p-type active region; an insulated gate electrode structure formed on each of the active regions, and having a gate insulating film and a gate electrode formed thereon; side wall spacers formed on side walls of the insulated gate electrode structures; source/drain regions having extension regions having the opposite conductivity type to that of the active region and formed on both sides of the insulated gate electrode structures and source/drain diffusion layers having the opposite conductivity type and formed in the active regions outside of the side wall spacers; first recess regions formed by digging down the n-type source/drain regions in the p-type active region from surfaces of the n-type source/drain regions; and a first nitride film having tensile stress formed covering the p-type active region and burying the first recess regions.

Abstract: A semiconductor device which includes a laterally extending stack of laterally adjacent conductive semiconductor regions formed over a support surface of a substrate, and a method for fabricating the device.

Abstract: A method of manufacturing a bipolar-complementary metal oxide semiconductor (BiCMOS) is provided. A gate in a CMOS area and a conductive layer pattern defining an opening, which opens an active region in a bipolar transistor area, are simultaneously formed by patterning a gate conductive layer. Thereafter, bipolar transistor manufacturing processes are performed while CMOS manufacturing processes are performed. Accordingly, the number of masks is decreased, and degradation of device characteristics is prevented.

Abstract: A process for forming bipolar junction transistors having a plurality of different collector doping densities on a semiconductor substrate and an integrated circuit comprising bipolar junction transistors having a plurality of different collector doping densities. A first group of the transistors are formed during formation of a triple well for use in providing triple well isolation for complementary metal oxide semiconductor field effect transistors also formed on the semiconductor substrate. Additional bipolar junction transistors with different collector doping densities are formed during a second doping step after forming a gate stack for the field effect transistors. Implant doping through bipolar transistor emitter windows forms bipolar transistors having different doping densities than the previously formed bipolar transistors.

Abstract: Disclosed are an arrangement and a production method for electrically connecting (20) active semiconductor structures (40) in the monocrystalline silicon layer (12) located on the front face of silicon-on-insulator semiconductor wafers (SOI; 10) to the substrate (13) located on the rear side and additional structures (13a) that are disposed therein. The electrical connection is made through the insulator layer (11).

Abstract: Methods and systems for fabricating integrated pairs of HBT/FET's are disclosed. One preferred embodiment comprises a method of fabricating an integrated pair of GaAs-based HBT and FET. The method comprises the steps of: growing a first set of epitaxial layers for fabricating the FET on a semi-insulating GaAs substrate; fabricating a highly doped thick GaAs layer serving as the cap layer for the FET and the subcollector layer for the HBT; and producing a second set of epitaxial layers for fabricating the HBT.