Abstract: A new method of fabricating a stacked gate Flash EEPROM device having an improved stacked gate topology is described. Isolation regions are formed on and in a semiconductor substrate. A tunneling oxide layer is provided on the surface of the semiconductor substrate. A first polysilicon layer is deposited overlying the tunneling oxide layer. The first polysilicon layer is polished away until the top surface of the polysilicon is flat and parallel to the top surface of the semiconductor substrate. The first polysilicon layer is etched away to form the floating gate. The source and drain regions are formed within the semiconductor substrate. An interpoly dielectric layer is deposited overlying the first polysilicon layer. A second polysilicon layer is deposited overlying the interpoly dielectric layer. The second polysilicon layer and the interpoly dielectric layer are etched away to form a control gate overlying the floating gate. An insulating layer is deposited overlying the oxide layer and the control gate.

Abstract: A complementary bipolar transistor device, made of two separate conductive films such as two highly doped polysilicon films of opposite conductivity types. The doped polysilicon film is used for a base of NPN transistor and an emitter of a PNP transistor whereas the other doped polysilicon film is used for emitter of the NPN and a base of the PNP. The resulting base and emitter isolating structure is easy to fabricate, and self-aligned to the advantage of size reduction of individual devices.

Abstract: A manufacturing method for semiconductor components is disclosed which will allow better precision in the definition of the doped areas of the components and the separation of differently doped areas. A selectively shaped area of, for example, polysilicon, defining the area or areas to be doped, is deposited on the component before the masks are applied. This makes the fitting of the masks less critical, as they only have to be fitted within the area of the polysilicon layer. In this way an accuracy of 0.1 .mu.m or better can be achieved.

Abstract: A relatively simple method for providing relatively close spacing between the emitter mesa and the base ohmic metal of a heterojunction bipolar transistor (HBT) on a relatively uniform basis. An emitter and base layer are epitaxially grown on a substrate. An emitter mesa is patterned with an i-line negative photoresist using conventional photolithography. Baking before and after exposure is used to form a resist pattern with a re-entrant profile having about a 0.1 .mu.m resist overhang. The emitter layer is then etched with a wet etch and or isotropic dry etch to expose a portion of the base ohmic metal to make contact with the base. A second layer of an i-line negative photoresist is applied over the first photoresist. The second layer is used to pattern the base ohmic metal mask. The base ohmic metal is deposited by evaporation.

Abstract: A method of fabricating an HBT using differential epitaxy. By using an emitter mask and an exside-inside spacer structure, a self-aligned fabrication of an emitter contact and a base contact is carried out. The emitter contact layer is made from amorphous silicon. Since the entire process sequence is very temperature-stable and can be carried out at lower implantation energies than conventional methods, HBT's having a high layer quality can be fabricated by the method of the invention which is suitable for mass production and with which high oscillation frequencies can be accomplished.

Abstract: A method for controlling the spacing between the emitter mesa and the base ohmic metal of a heterojunction bipolar transistor (HBT) to obtain a relatively high gain (.beta.) with a low-parasitic base resistance. In a first method, after the emitter, base and collector layers are epitaxially grown on a substrate, a sacrificial layer is deposited on top of the emitter layer. The emitter mesa is patterned with a photoresist using conventional lithography. Subsequently, the sacrificial layer is etched to produce an undercut. The emitter layer is then etched and a photoresist is applied over the first photoresist used to pattern the emitter mesa, as well as the entire device. The top layer of photoresist is patterned with a conventional process for lift-off metalization, such that the final resist profile has a re-entrant slope. The base ohmic metal is deposited and then lifted off by dissolving both the second layer of photoresist, as well as the original photoresist over the emitter mesa.

Abstract: A BiCMOS device and a manufacturing method thereof according to the present invention has a gate insulating layer of NMOSFET having non-uniform thickness. The thickness of the end portion of the gate insulating layer, which is near LDD regions, is thicker than that of center portion. Therefore, the GIDL and the gate-drain overlap capacitance is reduced. In addition, in case of the bipolar transistor of the BiCMOS device, there exists a portion of an oxide film below the side portion of the emitter polysilicon and over the side portions of the emitter region. Since this structure serves as a gate of field effect transistor, N- channel is produced in the emitter region when the emitter-base junction is reversely biased and thus the hot carrier reliability is improved.