Abstract: During fabrication of an insulated gate device, a drain-forming dopant having a relatively low diffusion coefficient is implanted along a substrate surface which overlaps the boundary between a to-be-formed vertical drain region and a to-be-formed adjacent channel region. During subsequent high temperature processing the low diffusion coefficient drain-forming dopant remains concentrated near the top surface of the substrate while other well-forming dopants, including an adjacent channel-forming dopant, which have relatively higher diffusion coefficients, diffuse to deeper regions of the substrate. The slow-diffusing drain-forming dopant retards lateral widening of the channel by the faster-diffusing channel-forming dopant just below the substrate surface to at least the depth of the channel inversion layer formed under the channel surface during device turn on.

Abstract: An orthogonal bipolar transistor structure is disclosed which is particularly suitable for formation in relatively thin epitaxial layers on insulating substrates. The emitter of the transistor is disposed directly over the base region while a collector region may be arranged on one side of or surrounding the base region. Alternatively, the collector region may be a pair of regions disposed laterally on opposite sides of the base region.

Abstract: A vertical MOSFET in a silicon wafer having opposing major surfaces includes a source electrode on one surface, a drain electrode on the second surface, and an internally disposed insulated gate. The silicon between the insulated gate and each of the major surfaces is of first conductivity type and the silicon that is laterally adjacent to the insulated gate is of second conductivity type, such that a predetermined voltage on the insulated gate creates an inversion channel extending a predetermined distance into the laterally adjacent silicon. That portion of the laterally adjacent silicon where the inversion channel is formed is of relatively lightly doped material, whereas other areas of the laterally adjacent silicon is relatively heavily doped.

Abstract: A semiconductor wafer is appropriately doped to create a P-N or P-I-N junction, and metallized on both its planar surfaces with electrode material. The wafer is then bonded to a second similarly processed wafer. Without damaging the semiconductor material, the stacked wafer is processed so as to delineate a plurality of diodes on each side of the center metallization, such that the diodes on each side are registered with each other. The center metallization is then cut so as to yield a plurality of stacked semiconductor diodes.