Abstract: The invention relates to a method of manufacturing a semiconductor device comprising a substrate (1) and a semiconductor body (2) in which at least one semiconductor element is formed, wherein, in the semiconductor body (2), a semiconductor island (3) is formed by forming a first cavity (4) in the surface of the semiconductor body (2), the walls of said first cavity being covered with a first dielectric layer (6), after which, by means of underetching through the bottom of the cavity (4), a lateral part of the semiconductor body (2) is removed, thereby forming a cavity (20) in the semiconductor body (2) above which the semiconductor island (3) is formed, and wherein a second cavity (5) is formed in the surface of the semiconductor body (2), the walls of said second cavity being covered with a second dielectric layer, and one of the walls covered with said second dielectric layer forming a side wall of the semiconductor island (3).

Abstract: A method for forming a semiconductor device includes forming a photoresist layer over a substrate and patterning the photoresist layer to form photoresist portions. A second layer is formed over the substrate in areas not covered by the photoresist portions and the photoresist portions are removed. After removing the photoresist portions, the second layer is used to modify the substrate to create at least a portion of the semiconductor device.

Abstract: Methods are disclosed for fabricating a compound nitride semiconductor structure. An amorphous buffer layer that includes nitrogen and a group-III element is formed over a substrate disposed within a substrate processing chamber at a first temperature. The temperature within the chamber is increased to a second temperature at which the amorphous buffer layer coalesces into crystallites over the substrate. The substrate is exposed to a corrosive agent to destroy at least some of the crystallites. A crystalline nitride layer is formed over the substrate at a third temperature using the crystallites remaining after exposure to the corrosive agent as seed crystals. The third temperature is greater than the first temperature. The crystalline nitride layer also includes nitrogen and a group-III element.

Abstract: A method of manufacturing a semiconductor device. The device includes a plurality of layers on a semiconductor substrate. The method includes the steps of dividing a pattern of at least one layer into a plurality of sub-patterns, and joining the divided sub-patterns to perform patterning. A layer that includes wiring substantially affects operation of the semiconductor device depending on a positional relationship to any other wiring. The patterning is performed by one-shot exposure using a single mask.

Abstract: A process for making an integrated circuit is described wherein sequence of mask steps is applied to a substrate or epitaxial layer of p-type material. The sequence consists of sixteen specific mask steps that permit a variety of bipolar/CMOS/DMOS devices to be fabricated. The mask steps include (1) forming at least one N-well in the p-type material, (2) forming an active region, forming a p-type field region, (4) forming a gate oxide, (5) carrying out a p-type implantation, (6) forming polysilicon gate regions, (7) forming a p-base region, (8) forming a N-extended region, (9) forming a p-top region, 10) carrying out an N+ implant, (11) carrying out a P+ implant, (12) forming contacts, (13) depositing a metal layer, (14) forming vias, (15) depositing a metal layer therethrough, and (16) forming a passivation layer. Up to any three of mask steps (4), (7), (8), and (9) may be omitted depending on the type of integrated circuit.

Abstract: A resin-encapsulation semiconductor device of this invention includes a die pad for mounting a semiconductor element; a plurality of supporting leads; a semiconductor element; a plurality of leads disposed to have tips thereof opposing the die pad; metal wires; and an encapsulation resin for encapsulating the die pad excluding a bottom thereof, the leads excluding bottoms and outside edges thereof, connecting regions with the metal wires, the supporting leads and the semiconductor element. The outside edges of the leads are disposed on substantially the same plane as the side face of the encapsulation resin, and the tip of each lead has a thin portion where the thickness is reduced in an upper face thereof.