Abstract: A Bipolar Junction Transistor (BJT) that reduces the variation in the current gain through the use of a trench pullback structure. The trench pullback structure is comprised of a trench and an active region. The trench reduces recombination in the emitter-base region through increasing the distance charge carriers must travel between the emitter and the base. The trench also reduces recombination by reducing the amount of interfacial traps that the electrons injected from the emitter are exposed to. Further, the trench is pulled back from the emitter allowing an active region where electrons injected from a sidewall of the emitter can contribute to the overall injected emitter current. This structure offers the same current capability and current gain as a device without the trench between the emitter and the base while reducing the current gain variation.

Abstract: A semiconductor component includes a semiconductor substrate (310) having a first conductivity type, a first semiconductor device (320) at least in a first portion of the semiconductor substrate, and a second semiconductor device (330, 310) at least in a second portion of the semiconductor substrate. The first semiconductor device includes a first electrode region (321), a second electrode region (322), a body region (323), and an isolation region (324) in the first portion of the semiconductor substrate. The body region has the first conductivity type, and the first electrode region, the second electrode region, and the isolation region have a second conductivity type. The second electrode region has a different doping concentration than the first electrode region, and the body region is isolated from the second portion of the semiconductor substrate by the isolation region and the first electrode region.

Abstract: A method of manufacturing a semiconductor component includes providing a substrate (110) having a first doping concentration and growing an epitaxial layer (120, 520) over the substrate. The epitaxial layer has a second doping concentration lower than the first doping concentration, and the epitaxial layer has at least two effective, as-grown thicknesses. The resulting composite substrate is suitable for an integrated circuit having both high and low voltage portions.

Abstract: A vertically diffused FET (10) is fabricated on a semiconductor die (11) that includes an N+ substrate (12) and an N− epitaxial layer (14). The FET (10) has a source region (36) and a channel region (38) near a front surface (15) of the epitaxial layer (14), and a drain region in the substrate (12). A trench (22) extends through the epitaxial layer (14) to the substrate (12). A conductive layer (24) fills the trench (22), thereby forming a conductive plug (25) electrically coupled to the substrate (12). The conductive plug (25) forms a top side drain electrode of the FET (10).

Abstract: A method for selectively forming semiconductor regions (28) is provided, by exposing a patterned substrate (21) having exposed regions of semiconductor material (26,27) and exposed regions of oxide (24) to a first temperature and a semiconductor source-gas and hydrogen in an atmosphere substantially absent halogens, a blanket semiconductor layer (28,29) forms over the exposed regions of semiconductor material (26,27) and oxide (24). By further exposing the patterned substrate (21) to a second temperature higher than the first temperature in a hydrogen atmosphere, polycrystalline semiconductor material (29) formed over the exposed oxide regions (24) is selectively removed leaving that portion of the blanket semiconductor layer (28) over the exposed regions of semiconductor material (26,27). The method is suitable for forming isolated regions of semiconductor material for fabricating semiconductor devices and is not load dependent.