Abstract: A method of anisotropically plasma etching a silicon on insulator substrate wherein undercutting is substantially eliminated by utilizing as a finishing etch step a reactive ion etching process wherein the ion density is reduced in order to limit ion charging through different size recesses in order to uniformly etch in a vertical direction.

Abstract: A flexible, multilayer thin film capacitor comprises a flexible substrate and at least two electrode layers mounted on the substrate alternately with at least one dielectric layer. The dielectric layer may include amorphous hydrogenated carbon. The at least two electrode layers and the at least one dielectric layer are capable of acting as at least one capacitor, and the flexible substrate is capable of being manipulated so as to have a desired shape.

Abstract: Capacitors with high dielectric strength and low dissipation factor over a wide range of frequencies comprise two or more conductive layers separated by at least one dielectric layer. The dielectric layer is of silicon-doped amorphous hydrogenated carbon, with suitable dopants including silane (which is preferred), tetraalkoxysilanes and polyorganosiloxanes.

Abstract: Power semiconductor device structures and assemblies with improved heat dissipation characteristics and low impedance interconnections include a thermally-conductive dielectric layer, such as diamondlike carbon (DLC) overlying at least portions of the active major surface of a semiconductor chip, with vias formed in the dielectric layer in alignment with contact pads on the active major surface. A patterned metallization layer is formed over the thermally-conductive dielectric layer, with portions of the metallization layer extending through the vias into electrical contact with the chip contact pads. A metal structure is electrically and thermally coupled to selected areas of the patterned metallization, such as by solder bonding or by a eutectic bonding process. In different embodiments, the metal structure may comprise a metal conductor bonded to the opposite major surface of another power semiconductor device structure, a heat-dissipating device-mounting structure, or simply a low-impedance lead.

Abstract: The electrical field at the surface of an electrode is graded by depositing a semiconductive coating thereon. An electrode substrate is powered at a preselected temperature and power. A mixture of gases is then passed through an electrical discharge to ionize at least a portion thereof to form the semiconductive coating on the surface of the electrode. A diamondlike carbon (DLC) film is deposited by plasma enhanced chemical vapor deposition onto a substrate. A substrate is maintained at a preselected DLC forming temperature and is negatively biased at a first preselected voltage. A first gaseous mixture of hydrocarbons and argon is then passed through an electrical discharge to at least partially ionize the hydrocarbons to form DLC film on the substrate. The substrate is then negatively biased at a second preselected voltage lower than the first preselected voltage.