Abstract: Devices and methods are presented to fabricate dummy moats in an isolation region on a substrate. Presently, dummy moats are prone to losing impedance after the silicidation process. In high-voltage devices, silicided dummy moats reduce the breakdown voltage between active regions, particularly when the dummy moat overlaps or is in close proximity to a junction. The present devices and methods disclose a dummy moat covered with an oxide layer. During the silicidation process, the dummy moat and other designated isolation regions remain non-silicided. Thus, high and stable breakdown voltages are maintained.

Abstract: We disclose the structure of a JFET device, the method of making the device and the operation of the device. The device is built near the top of a substrate. It has a buried layer that is electrically communicable to a drain terminal. It has a channel region over the buried layer contacting gate regions that connect to a gate terminal. The channel region, of which the length spans the distance between the buried layer and a source region, is connected to a source terminal. The device current flows in the channel substantially perpendicularly to the top surface of the substrate.

Abstract: The present invention provides, in one embodiment, a transistor (100). The transistor (100) comprises a doped semiconductor substrate (105) and a drain-extended well (115) having a curved region (125) and a straight region (130) surrounded by the doped semiconductor substrate (105). The drain-extended well (115) has an opposite dopant type as the doped semiconductor substrate (105). The transistor (100) further includes a centered source/drain (120) surrounded by the drain-extended well (115) and separated from an outer perimeter (135) of the drain-extended well (115). A separation in the curved region (145) is greater than a separation in the straight region (150). Other embodiments of the present invention include an integrated circuit (300) and a method of manufacturing a transistor (200).

Abstract: The present invention provides, in one embodiment, a transistor (100). The transistor (100) comprises a doped semiconductor substrate (105) and a drain-extended well (115) having a curved region (125) and a straight region (130) surrounded by the doped semiconductor substrate (105). The drain-extended well (115) has an opposite dopant type as the doped semiconductor substrate (105). The transistor (100) further includes a centered source/drain (120) surrounded by the drain-extended well (115) and separated from an outer perimeter (135) of the drain-extended well (115). A separation in the curved region (145) is greater than a separation in the straight region (150). Other embodiments of the present invention include an integrated circuit (300) and a method of manufacturing a transistor (200).

Abstract: We disclose the structure of a JFET device, the method of making the device and the operation of the device. The device is built near the top of a substrate. It has a buried layer that is electrically communicable to a drain terminal. It has a channel region over the buried layer contacting gate regions that connect to a gate terminal. The channel region, of which the length spans the distance between the buried layer and a source region, is connected to a source terminal. The device current flows in the channel substantially perpendicularly to the top surface of the substrate.