Abstract: A method for forming a heterojunction bipolar transistor includes forming an epitaxial layer, forming a first polysilicon layer, and forming a dielectric layer on the first polysilicon layer. The first polysilicon layer and the dielectric layer include an opening for exposing a portion of the top surface of the epitaxial layer. Then, a silicon germanium layer is selectively grown in the opening. The silicon germanium layer is grown on the exposed top surface of the epitaxial layer and on the exposed sidewall of the first polysilicon layer. Next, a spacer is formed along the sidewalls of the dielectric layer and the silicon germanium layer. A second polysilicon layer in electrical contact with the silicon germanium layer is then formed. Accordingly, a low resistance connection between the first polysilicon layer forming the extrinsic base region and the silicon germanium layer forming the intrinsic base region of the transistor is formed.

Abstract: A method for forming a heterojunction bipolar transistor includes forming an epitaxial layer, forming a first polysilicon layer, and forming a dielectric layer on the first polysilicon layer. The first polysilicon layer and the dielectric layer include an opening for exposing a portion of the top surface of the epitaxial layer. Then, a silicon germanium layer is selectively grown in the opening. The silicon germanium layer is grown on the exposed top surface of the epitaxial layer and on the exposed sidewall of the first polysilicon layer. Next, a spacer is formed along the sidewalls of the dielectric layer and the silicon germanium layer. A second polysilicon layer in electrical contact with the silicon germanium layer is then formed. Accordingly, a low resistance connection between the first polysilicon layer forming the extrinsic base region and the silicon germanium layer forming the intrinsic base region of the transistor is formed.

Abstract: An oxide-isolated RAM and PROM process is disclosed wherein a RAM circuit includes a lateral PNP transistor formed in the same island of silicon material as a vertical NPN device and further wherein contact is made to the base of the lateral PNP and to the collector of the vertical NPN through a buried contact region accessed through a sink region formed in an adjacent island of semiconductor material. A field implantation beneath the isolation oxide avoids implanting impurity along the sidewalls of the semiconductor material adjacent the field oxidation and therefore provides both vertical and lateral isolation from one silicon island to another. Substantial reductions in sink sizes and cell sizes are obtained by eliminating the field diffusions from the sidewalls of the semiconductor islands. The lateral PNP transistor serves as an active load for a memory circuit constructed using the structure of this invention. The process also can be used to manufacture PROMs from vertical NPN transistors. An LV.sub.

Abstract: An oxide-isolated RAM and PROM process is disclosed wherein a RAM circuit includes a lateral PNP transistor formed in the same island of silicon material as a vertical NPN device and further wherein contact is made to the base of the lateral PNP and to the collector of the vertical NPN through a buried contact region accessed through a sink region formed in an adjacent island of semiconductor material. A field implantation beneath the isolation oxide avoids implanting impurity along the sidewalls of the semiconductor material adjacent the field oxidation and therefore provides both vertical and lateral isolation from one silicon island to another. Substantial reductions in sink sizes and cell sizes are obtained by elminating the field diffusions from the sidewalls of the semiconductor islands. The lateral PNP transistor serves as an active load for a memory circuit constructed using the structure of this invention. The process also can be used to manufacutre PROMS from vertical NPN transistors. An LV.sub.

Abstract: A lateral bipolar transistor having a base width of 0.