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 fabrication of a bipolar transistor using an enhanced trench isolation so as to improve integration and performance thereof, comprising the steps of sequentially etching back portions corresponding to a trench using a trench forming mask to a predetermined depth of the buried collector to form the trench; filling an isolation insulating layer into the trench; polishing the isolation insulating layer up to a surface of the silicon oxide layer; sequentially forming a second insulating layer on the isolating insulating layer and the silicon oxide layer; removing the first polysilicon layer and the first insulating layer formed on an inactive region other than an active region defined by the trench; thermal-oxidizing the collector layer formed on the inactive region to form a thermal oxide layer; removing the second insulating layer and sequentially forming a third polysilicon, a third insulating layer and a second nitride layer; etching back layers formed on a portion of the first insulating layer

Abstract: Disclosed is a fabrication of a bipolar transistor with a super self-aligned vertical structure in which emitter, base and collector are vertically self-aligned, the fabrication method comprising the steps of forming a conductive buried collector region in a silicon substrate by using ion-implantation of an impurity and thermal-annealing; sequentially forming several layers; selectively removing the nitride and polysilicon layers to form a pattern; sequentially forming a silicon oxide layer, a third layer and a silicon oxide layer thereon; forming a patterned photoresist layer thereon to define active and inactive regions and removing several layers on the active region to form an opening; forming a side wall on both sides of the opening; forming a collector on a surface portion of the buried collector region up to a lower surface of the polysilicon layer; removing the side wall and the third nitride layer to expose a side surface of the second polysilicon layer; selectively forming a base on an upper surface

Abstract: Disclosed is a fabrication of a hetero-junction bipolar transistor in which a base parasitic capacitance is fully reduced by using a metallic silicide as a base, comprising the steps of injecting an impurity in a silicon substrate to form a conductive buried collector region; growing a collector epitaxial layer on the buried collector region and forming a field oxide layer; selectively injecting an impurity into the collector epitaxial layer to form a collector sinker; sequentially forming a base layer and an first oxide layer thereon; patterning the first oxide layer to define an extrinsic base region; ion-implanting an impurity in the extrinsic base region using a patterned oxide layer as a mask and removing the patterned oxide layer; depositing a metallic silicide film thereon to form a base electrode thin film; forming a capping oxide layer of about 500 .ANG.

Abstract: Disclosed is a method of fabricating an SOI substrate, comprising the steps of forming a first insulating layer on a single crystal silicon substrate; patterning the first insulating layer to form an opening; growing a single crystal silicon in the opening to form active and inactive regions; polishing the active region 31 as the first insulating layer as a polishing stopper to form a planarized surface; depositing a second insulating layer on the planarized surface; bonding a bonding substrate to the second insulating layer; and polishing the silicon substrate using the first insulating layer as a stopper up to a surface of the active region. By the method, a stray capacitance occurring between an SOI substrate and a metal wiring portion formed thereon can be significantly reduced owing to a relatively thick insulating layer therebetween, and a parasitic capacitance can be eliminated owing to an insulating layer interposed between a bonding substrate and an active region to be used as a buried collector.