Abstract: A method for isolating a semiconductor device is disclosed including the steps of sequentially growing a plurality of material layers on a semiconductor substrate, etching the material layers down to a predetermined depth of the substrate to thereby define an active region, forming a semi-insulating film on the exposed semiconductor substrate in order to planarize the step-difference of the active region and the isolation region, and then, forming an ohmic metal layer on a space where the semi-insulating film is regrown.

Abstract: The invention relates to a method for manufacturing a super self-aligned heterojunction bipolar transistor which is capable of miniaturizing an element, simplifying the process step thereof by employing a selective collector epitaxial growth and a polycide base electrode without using a trench for isolating between elements, thereby enhancing the performance thereof, which comprises the steps of: forming sequently a first oxidation film, an electrically conducting thin film and a second oxidation film on top of a substrate; patterning the second oxidation film and the conducting thin film to form a preliminary spacer; removing an exposed portion of the first oxidation film, and selectively growing a collector layer; oxidizing the collector layer to form a thermal oxidation film, and removing the preliminary spacer; depositing a polysilicon and forming a silicon oxidation film and a polysilicon spacer on the second oxidation film and the removed portion of the preliminary spacer, respectively; exposing the bas

Abstract: A silicon/silicon-germanium bipolar transistor fabrication method employs a metallic silicide film as an extrinsic base electrode to reduce resistance of the extrinsic base electrode, and to increase a maximum oscillation frequency and cut-off frequency due to its self-aligned structure. The fabrication method enables agglomeration to occur on the side wall of the polycrystalline silicon film connected to the metallic silicide film instead of on the interface between the metallic silicide film and the lower silicon/silicon-germanium film, and leads the extrinsic base electrode to be sandwitched by the insulator films, thereby realizing a constant resistance and also resulting in the application of integrated circuits to a mass production mechanism.

Abstract: Disclosed is a method of fabricating a metal semiconductor field effect transistor, comprising the steps for, forming the channel using an ion-implantation, sequentially forming a first insulator layer at a first predetermined temperature and a second insulation layer at second predetermined temperature over the surface of the substrate, etching the first and second insulation layers using a gate pattern of a photo-resist pattern to expose the channel region as a mask, forming a refractory metal over the surface of the first and second insulation layer add the exposed channel region, etching the refractory metal, thereby dividing it into two parts of which one is formed on the channel region and the other is formed on the second insulation layer, selectively etching the first and second insulation layers to lift-off the refractory metal over the first and second insulation layers, thereby forming a gate of a T-shape on the channel region, ion implanting Si into a substrate using the gate and a channel pattern