Abstract: A method of making a semiconductor switch device and a semiconductor switch device made according to the method. The method includes depositing a gate dielectric on a major surface of a substrate. The method also includes depositing and patterning a gate electrode on the gate dielectric. The method further includes depositing an oxide to cover the top surface and sidewall(s) of the gate electrode. The method also includes, after depositing the oxide, performing a first ion implantation process at a first implantation dosage for forming a lightly doped drain region of the switch device. The method further includes forming sidewall spacers on the sidewall(s) of the gate electrode. The method also includes performing a second ion implantation process at a second implantation dosage for forming a source region and a drain region of the semiconductor switch device. The second implantation dosage is greater than the first implantation dosage.

Abstract: A method of making a semiconductor switch device and a semiconductor switch device made according to the method. The method includes depositing a gate dielectric on a major surface of a substrate. The method also includes depositing and patterning a gate electrode on the gate dielectric. The method further includes depositing an oxide to cover the top surface and sidewall(s) of the gate electrode. The method also includes, after depositing the oxide, performing a first ion implantation process at a first implantation dosage for forming a lightly doped drain region of the switch device. The method further includes forming sidewall spacers on the sidewall(s) of the gate electrode. The method also includes performing a second ion implantation process at a second implantation dosage for forming a source region and a drain region of the semiconductor switch device. The second implantation dosage is greater than the first implantation dosage.

Abstract: Fabrication of a mono-crystalline emitter using a combination of selective and differential growth modes. The steps include providing a trench (14) formed on a silicon substrate (16) having opposed silicon oxide side walls (12); selectively growing a highly doped mono-crystalline layer (18) on the silicon substrate in the trench; and non-selectively growing a silicon layer (20) over the trench in order to form an amorphous polysilicon layer over the silicon oxide sidewalls.

Abstract: Fabrication of a mono-crystalline emitter using a combination of selective and differential growth modes. The steps include providing a trench (14) formed on a silicon substrate (16) having opposed silicon oxide side walls (12); selectively growing a highly doped mono-crystalline layer (18) on the silicon substrate in the trench; and non-selectively growing a silicon layer (20) over the trench in order to form an amorphous polysilicon layer over the silicon oxide sidewalls.

Abstract: The present invention provides for a method of fabricating a semiconductor device comprising a non-selectively grown SiGe(C) heterojunction bipolar transistor including the steps of forming an insulating layer (12, 40) on a substrate and providing a layer structure including a conductive layer (14, 42) on the insulating layer (12, 40), etching a transistor area opening (12, 44) through the conductive layer (14, 42), depositing a SiGe base layer (24, 46) on the inner wall of the transistor area opening (22, 44) and forming an insulator (32, 52) on an upper surface so as to fill the transistor area opening wherein prior to the filling step, a nitride layer (30, 50) is formed as an inner layer of the transistor area opening (22, 44).

Abstract: A method of manufacturing a semiconductor device comprising a poly-emitter transistor (1) and a capacitor (2). A base electrode (14), a first electrode (16, 37) and an emitter window (18) are formed at the same time in a first polysilicon layer (13) covered with an insulating layer (25). Subsequently, the side walls of the electrodes (20, 39) and the wall (23) of the emitter window are covered at the same time with insulating spacers (22, 44) by depositing a layer of an insulating material, followed by an anisotropic etching process. The base (8) of the transistor is formed by ion implantation. The emitter (9) is formed by diffusion, from an emitter electrode (30) formed in a second polysilicon layer. Preferably, the first electrode of the capacitor consists of mutually connected strips (37).