Abstract: A first dielectric layer (22) is formed over a semiconductor device substrate. A resist layer (32) is then patterned to expose portions of the first dielectric layer (22). Portions of the first dielectric layer (22) are removed to expose portions of the semiconductor device substrate (42). The resist layer (32) is then removed. The semiconductor device substrate is cleaned without using a fluorine-containing solution and a second dielectric layer (62) is formed overlying the semiconductor device substrate.

Abstract: A method for forming a dual gate oxide (DGO) structure begins by forming a first oxide layer (106) within active areas (110) and (112). A protection layer (108a) is then formed over the layer (106). A mask (114) is used to allow removal of the layers (106 and 108a) from the active area (110). A thermal oxidation process is then used to form a thin second oxide layer (118) within an active area (110). Conductive gate electrodes (120a and 120b) are then formed wherein the first oxide layer (106) and the protection layer (108c) are incorporated into the gate dielectric layer of an MOS transistor (122a). The transistor (122b) has a thinner gate oxide layer that excludes the protection layer (108c).

Abstract: Lithographic Proximity Correction (LPC) shapes are added (503) to a layer of a layout database file (501). Geometric criteria such as feature width are then used to filter the added LPC shapes (502). The LPC shapes are then modified (505) by determining which LPC shapes are within a predetermined distance from a shape in a layer of the second data base (504). The database file, including the modified LPC shapes, is then used to manufacture a set of lithographic masks (506). The lithographic masks are then used to pattern a set of wafers in the manufacture of integrated circuits (507).

Abstract: An SOI structure (20) includes a semiconductor layer (15) formed on an insulating substrate (12). The semiconductor layer (15) is partitioned into an ESD protection portion (32) and a circuitry portion (34). A portion of the semiconductor layer (15) in the ESD protection portion (32) and a different portion of the semiconductor layer (15) in the circuitry portion (34) are differentially thinned. A device (60) which implements the desired circuit functions of the SOI structure (20) is fabricated in the circuitry portion (34). An ESD protection device (40) is fabricated in the ESD protection portion (32). The thick semiconductor layer (15) in the ESD protection portion (32) serves to distribute the ESD current and heat over a large area, thereby improving the ability of the SOI structure (20) to withstand an ESD event.

Abstract: A semiconductor device with an electrostatic discharge (ESD) protection transistor is devised, wherein the ESD protection transistor has halo regions of an opposite conductivity type from the source and drain regions adjacent thereto. In one embodiment, the ESD protection transistor is a thick field oxide (TFO) transistor. In some cases, the halo regions may be provided with an ion implant step without the use of an extra mask. The halo regions permit the ESD protection transistor to have its breakdown voltage adjusted so that it turns on before the device it is protecting is affected by an ESD event. The use of halo regions avoids the increase in device area and adverse effects to the AC performance of the circuit being protected that are disadvantages of prior approaches.

Abstract: A semiconductor device with an electrostatic discharge (ESD) protection transistor is devised, wherein the ESD protection transistor has halo regions of an opposite conductivity type from the source and drain regions adjacent thereto. In one embodiment, the ESD protection transistor is a thick field oxide (TFO) transistor. In some cases, the halo regions may be provided with an ion implant step without the use of an extra mask. The halo regions permit the ESD protection transistor to have its breakdown voltage adjusted so that it turns on before the device it is protecting is affected by an ESD event. The use of halo regions avoids the increase in device area and adverse effects to the AC performance of the circuit being protected that are disadvantages of prior approaches.

Abstract: A process for the fabrication of an MOSFET device includes the formation of a buffer layer (28) overlying the surface of a semiconductor substrate (14) adjacent to a gate electrode (18). A defect compensating species is diffused through the buffer layer (28) and through a gate dielectric layer (12) to form a defect-compensating region (30) at the surface (14) of the semiconductor substrate (10). The defect-compensating region (30) in conjunction with the buffer layer (28) minimize and control the population of point defects in the channel region (22) of the semiconductor substrate (10). By controlling the population of point defects in the channel region (22), a substantially uniform doping profile is maintained in a shallow doped region (16) formed in the semiconductor substrate (10) at the substrate surface (14). The maintenance of a uniform doping profile in the shallow doped region (16) results in improved threshold voltage stability as the lateral dimension of the channel region (22) is reduced.

Abstract: A metal-semiconductor compound (72, 74, 76) is formed after a step that introduces nitrogen into regions (52, 54, 56) of the device (100). In one embodiment, a nitrogen-containing gas is exposed to surfaces (42, 44, 46) before forming a titanium layer (62) is deposited. A one-step anneal is performed to form titanium disilicide regions (72, 72, 76) that are in the C54 phase without thermal agglomeration or forming electrical shorts between the titanium disilicide regions (72, 74, 76).