Abstract: A transistor (10) has a substrate (12) and a diffusion (14). A gate conductive layer (18) overlies the substrate (12) and has a sidewall formed by an opening that exposes the substrate (12). A sidewall dielectric layer (22) formed laterally adjacent the conductive layer (18) sidewall functions as a gate dielectric for the transistor (10). A conductive region is formed within the opening. The conductive region has a first current electrode region (28) and a second control electrode region (34) and a channel region (30) laterally adjacent the sidewall dielectric layer (22). A plurality of transistors, each in accordance with transistor (10), can be stacked in a vertical manner to form logic gates such as NMOS or PMOS NAND, NOR, and inverter gates, and/or CMOS NAND, NOR, and inverter gates with multiple inputs.

Abstract: A semiconductor memory device is formed having a substrate (12). A diffusion (14) is formed within the substrate (12). A first vertical transistor stack (122) is formed. A second vertical transistor stack (124) is formed. The first vertical transistor stack (122) has a transistor (100) underlying a transistor (104). The second vertical transistor stack (124) has a transistor (102) underlying a transistor (106). The transistors (100 and 104) are connected in series, and the transistors (102 and 106) are connected in series. In a preferred form, transistors (100 and 102) are electrically connected as latch transistors for a semiconductor memory device and transistors (106 and 104) are connected as pass transistors. Two vertical stacks (126 and 128) form electrical interconnections (118 and 120) and resistive devices (134 and 138) for the semiconductor memory device.

Abstract: A transistor and a capacitor is used to provide, in one form, a dynamic random access memory (DRAM) cell (10). The capacitor of cell (10) lies within a substrate (12). The capacitor has a first capacitor electrode (16) and a second capacitor electrode (20). A dielectric layer (18) is formed as an inter-electrode capacitor dielectric. A first transistor current electrode (36) is formed overlying and electrically connected to the first capacitor electrode (16). A channel region (38) is formed overlying the first transistor current electrode (36). A second transistor current electrode (40) is formed overlying the channel region (38). A conductive layer (30) is formed laterally adjacent the channel region (38) and isolated from the substrate (12) by dielectric layers (22 and 28). A conductive layer (30) functions as a gate electrode for the transistor and a sidewall dielectric (34) functions as a gate dielectric.

Abstract: A method for forming a transistor and a capacitor to provide, in one form, a DRAM cell (10). The capacitor of cell (10) is formed within a substrate (12). The capacitor has a first capacitor electrode (16) and a second capacitor electrode (20). A dielectric layer (18) is formed as an inter-electrode capacitor dielectric. A first transistor current electrode (36) is formed overlying and electrically connected to the first capacitor electrode (16). A channel region (38) is formed overlying the first transistor current electrode (36). A second transistor current electrode (40) is formed overlying the channel region (38). A conductive layer (30) is formed laterally adjacent the channel region (38) and isolated from the substrate (12) by dielectric layers (22 and 28). A conductive layer (30) functions as a gate electrode for the transistor and a sidewall dielectric (34) functions as a gate dielectric.

Abstract: A transistor is formed as either a bipolar transistor (10) or an MOS transistor (11). Each transistor (10 or 11) has a substrate (12). Bipolar transistor (10) has a first current electrode (26) underlying a control electrode (28), and a second current electrode (32) overlying the control electrode (28). MOS transistor (11) has a first current electrode (54) underlying a channel region (56), and a source lightly doped region (58) and a source heavily doped region (60) overlying the channel region (56). A control electrode conductive layer (40) is laterally adjacent a sidewall dielectric layer (48), and sidewall dielectric layer (48) is laterally adjacent channel region (56). Conductive layer (40) functions as a gate electrode for transistor (11). Each of the transistors (10 and 11) is vertically integrated such as in a vertically integrated BiMOS circuit. Transistors (10 and 11) can be electrically isolated by isolation ( 64 and 66).

Abstract: A method for forming a grown bipolar transistor electrode contact wherein a substrate (12) is provided. A doped region (31) is formed within the substrate (12). A dielectric layer (26) is formed having an opening (36) which exposes a portion of the doped region (31). Conductive spacers (38) are formed adjacent a sidewall of the dielectric layer (26). A conductive region (34) is formed through either a selective process or an epitaxial process by using the conductive spacers (38) as a source for epitaxial or selective formation. The conductive region (34) forms the grown bipolar electrode contact by electrically contacting the doped region (31). The conductive region (34) is optionally overgrown in a lateral direction over a top surface of the dielectric layer (26) to form a self-aligned electrical contact pad for the doped region (31).

Abstract: A vertical transistor (10) has a substrate (12) and a control electrode conductive layer (18), which functions as a control or gate electrode. A sidewall dielectric layer (22) is formed laterally adjacent the control electrode conductive layer (18) and overlying the substrate (12). The conductive layer (18) at least partially surrounds a channel region (30). A vertical conductive region is formed within a device opening wherein a bottom portion of the conductive region is a first current electrode (28). A middle portion of the vertical conductive region is the channel region (30). A top portion of the vertical conductive region is a second current electrode (34).

Abstract: A vertical bipolar transistor (10) and a lateral bipolar transistor (11) are formed wherein both transistors (10 and 11) have a substrate (12). A dielectric layer (22) is formed overlying the substrate (12), and a conductive layer (24) is formed overlying the dielectric layer (22). Another dielectric layer (26) is formed overlying the conductive layer (24). A device opening is formed through the dielectric layers (22 and 26) and the conductive layer (24). A conductive region (33) is formed within the device opening and overlying the substrate (12). For transistor (10), the conductive region (33) is doped to form an active base electrode region (36) and a first current electrode region (38). A second current electrode region is formed via a diffusion (16). For transistor (11), a base electrode is formed via a diffused base region (46), and first and second current electrodes are respectively formed via diffused regions (44 and 48).