Abstract: An partially depleted Dieler LDMOSFET transistor (100) is provided which includes a substrate (150), a drift region (110) surrounding a drain region (128), a first well region (107) surrounding source region (127), a well buffer region (106) separating the drift region and first well region to at least partly define a first channel region, a gate electrode (118) formed over the first channel region having a source-side gate edge aligned with the first well region (107), an LDD extension region (120) extending from the source region to the channel region, and a dielectric RESURF drain extension structure (161) formed at the drain of the gate electrode (118) using the plurality of STI stripes (114).

Abstract: Semiconductor device structures and related fabrication methods are provided. An exemplary semiconductor device structure includes a first vertical drift region of semiconductor material, a second vertical drift region of semiconductor material, and a buried lateral drift region of semiconductor material that abuts the vertical drift regions. In one or more embodiments, the vertical drift regions and buried lateral drift region have the same conductivity type, wherein a body region of the opposite conductivity type overlies the buried lateral drift region between the vertical drift regions.

Abstract: Instability and drift sometimes observed in bipolar transistors, having a portion of the base extending to the transistor surface between the emitter and base contact, can be reduced or eliminated by providing a further doped region of the same conductivity type as the emitter at the transistor surface between the emitter and the base contact. The further region is desirably more heavily doped than the base region at the surface and less heavily doped than the adjacent emitter. In another embodiment, a still or yet further region of the same conductivity type as the emitter is provided either between the further region and the emitter or laterally within the emitter. The still or yet further region is desirably more heavily doped than the further region. Such further regions shield the near surface base region from trapped charge that may be present in dielectric layers or interfaces overlying the transistor surface.

Abstract: A trench-isolated RESURF diode structure (100) is provided which includes a substrate (150) in which is formed anode (130, 132) and cathode (131) contact regions separated from one another by a shallow trench isolation region (114, 115), along with a buried cathode extension region (104) formed under a RESURF anode extension region (106, 107) such that the cathode extension region (104) extends beyond the cathode contact (131) to be sandwiched between upper and lower regions (103, 106, 107) of opposite conductivity type.

Abstract: A trench-isolated RESURF diode structure (100) is provided which includes a substrate (150) in which is formed anode (130, 132) and cathode (131) contact regions separated from one another by a shallow trench isolation region (114, 115), along with a non-uniform cathode region (104) and peripheral anode regions (106, 107) which define vertical and horizontal p-n junctions under the anode contact regions (130, 132), including a horizontal cathode/anode junction that is shielded by the heavily doped anode contact region (132).

Abstract: Semiconductor device structures and related fabrication methods are provided. An exemplary method of fabricating a semiconductor device on a doped region of semiconductor material having a first conductivity type involves forming a first region having a second conductivity type within the doped region, forming a body region having the first conductivity type overlying the first region, and forming a drift region having the second conductivity type within the doped region, wherein at least a portion of the drift region abuts at least a portion of the first region. In one embodiment, the dopant concentration of the first region is less than the dopant concentration of the body region and different from the dopant concentration of the drift region.

Abstract: Semiconductor device structures and related fabrication methods are provided. An exemplary semiconductor device structure includes a first vertical drift region of semiconductor material, a second vertical drift region of semiconductor material, and a buried lateral drift region of semiconductor material that abuts the vertical drift regions. In one or more embodiments, the vertical drift regions and buried lateral drift region have the same conductivity type, wherein a body region of the opposite conductivity type overlies the buried lateral drift region between the vertical drift regions.

Abstract: A device includes a semiconductor substrate, a drift region in the semiconductor substrate and having a first conductivity type, an isolation region within the drift region, and around which charge carriers drift on a path through the drift region during operation, and a protection region adjacent the isolation region in the semiconductor substrate, having a second conductivity type, and disposed along a surface of the semiconductor substrate.

Abstract: A method of fabricating a reduced surface field (RESURF) transistor includes forming a first well in a substrate, the first well having a first conductivity type, doping a RESURF region of the first well to have a second conductivity type, doping a portion of the first well to form a drain region of the RESURF transistor, the drain region having the first conductivity type, and forming a second well in the substrate, the second well having the second conductivity type. A plug region is formed in the substrate, the plug region extending to the RESURF region.

Abstract: Instability and drift sometimes observed in bipolar transistors, having a portion of the base extending to the transistor surface between the emitter and base contact, can be reduced or eliminated by providing a further doped region of the same conductivity type as the emitter at the transistor surface between the emitter and the base contact. The further region is desirably more heavily doped than the base region at the surface and less heavily doped than the adjacent emitter. In another embodiment, a still or yet further region of the same conductivity type as the emitter is provided either between the further region and the emitter or laterally within the emitter. The still or yet further region is desirably more heavily doped than the further region. Such further regions shield the near surface base region from trapped charge that may be present in dielectric layers or interfaces overlying the transistor surface.

Abstract: A lateral-diffused-metal-oxide-semiconductor device having improved safe-operating-area is provided. The LDMOS device includes spaced-apart source and drain, separated by a first insulated gate structure, and spaced-apart source and body contact The spaced-apart source and BC are part of the emitter-base circuit of a parasitic bipolar transistor that can turn on prematurely, thereby degrading the SOA of prior art four-terminal LDMOS devices. Rather than separating the source and BC with a shallow-trench-isolation region as in the prior art, the semiconductor surface in the gap between the spaced-apart source and BC has there-over a second insulated gate structure, with its gate conductor electrically tied to the BC. When biased, the second insulated gate structure couples the source and BC lowering the parasitic resistance in the emitter-base circuit, thereby delaying turn-on of the parasitic transistor and improving the SOA of such 4-T LDMOS devices.

Abstract: A multi-region (81, 83) lateral-diffused-metal-oxide-semiconductor (LDMOS) device (40) has a semiconductor-on-insulator (SOI) support structure (21) on or over which are formed a substantially symmetrical, laterally internal, first LDMOS region (81) and a substantially asymmetric, laterally edge-proximate, second LDMOS region (83). A deep-trench isolation (DTI) wall (60) substantially laterally terminates the laterally edge-proximate second LDMOS region (83). Electric field enhancement and lower source-drain breakdown voltages (BVDSS) exhibited by the laterally edge-proximate second LDMOS region (83) associated with the DTI wall (60) are avoided by providing a doped SC buried layer region (86) in the SOI support structure (21) proximate the DTI wall (60), underlying a portion of the laterally edge-proximate second LDMOS region (83) and of opposite conductivity type than a drain region (31) of the laterally edge-proximate second LDMOS region (83).

Abstract: A method of fabricating a reduced surface field (RESURF) transistor includes forming a first well in a substrate, the first well having a first conductivity type, doping a RESURF region of the first well to have a second conductivity type, doping a portion of the first well to form a drain region of the RESURF transistor, the drain region having the first conductivity type, and forming a second well in the substrate, the second well having the second conductivity type. A plug region is formed in the substrate, the plug region extending to the RESURF region.

Abstract: A device includes a semiconductor substrate, source and drain regions in the semiconductor substrate, a channel region in the semiconductor substrate between the source and drain regions through which charge carriers flow during operation from the source region to the drain region, and a drift region in the semiconductor substrate, on which the drain region is disposed, and through which the charge carriers drift under an electric field arising from application of a bias voltage between the source and drain regions. A PN junction along the drift region includes a first section at the drain region and a second section not at the drain region. The drift region has a lateral profile that varies such that the first section of the PN junction is shallower than the second section of the PN junction.

Abstract: Adverse tradeoff between BVDSS and Rdson in LDMOS devices employing a drift space (52, 152) adjacent the drain (56, 156), is avoided by providing a lightly doped region (511, 1511) of a first conductivity type (CT) separating the first CT drift space (52, 152) from an opposite CT WELL region (53, 153) in which the first CT source (57, 157) is located, and a further region (60, 160) of the opposite CT (e.g., formed by an angled implant) extending through part of the WELL region (53, 153) under an edge (591, 1591) of the gate (59, 159) located near a boundary (531, 1531) of the WELL region (53, 153) into the lightly doped region (511, 1511), and a shallow still further region (66, 166) of the first CT Ohmically coupled to the source (57, 157) and ending near the gate edge (591, 159) whereby the effective channel length (61, 161) in the further region (60, 160) is reduced to near zero.

Abstract: A device includes a semiconductor substrate including a surface, a drain region in the semiconductor substrate having a first conductivity type, a well region in the semiconductor substrate on which the drain region is disposed, the well region having the first conductivity type, a buried isolation layer in the semiconductor substrate extending across the well region, the buried isolation layer having the first conductivity type, a reduced surface field (RESURF) region disposed between the well region and the buried isolation layer, the RESURF region having a second conductivity type, and a plug region in the semiconductor substrate extending from the surface of the substrate to the RESURF region, the plug region having the second conductivity type.

Abstract: A device includes a semiconductor substrate, a channel region in the semiconductor substrate having a first conductivity type, and a composite drift region in the semiconductor substrate, having a second conductivity type. The composite drift region includes a first drift region and a second drift region spaced from the channel region by the first drift region. The device further includes a drain region in the semiconductor substrate, spaced from the channel region by the composite drain region, and having the second conductivity type. The first drift region has a dopant concentration profile with a first concentration level where adjacent the channel region and a second concentration level where adjacent the second drift region, the first concentration level being higher than the second concentration level. In some embodiments, the first and second drift regions are stacked vertically, with the first drift region being shallower than the second drift region.

Abstract: A disclosed power transistor, suitable for use in a switch mode converter that is operable with a switching frequency exceeding, for example, 5 MHz or more, includes a gate dielectric layer overlying an upper surface of a semiconductor substrate and first and second gate electrodes overlying the gate dielectric layer. The first gate electrode is laterally positioned overlying a first region of the substrate. The first substrate region has a first type of doping, which may be either n-type or p-type. A second gate electrode of the power transistor overlies the gate dielectric and is laterally positioned over a second region of the substrate. The second substrate region has a second doping type that is different than the first type. The transistor further includes a drift region located within the substrate in close proximity to an upper surface of the substrate and laterally positioned between the first and second substrate regions.

Abstract: A device includes a semiconductor substrate including a surface, a drain region in the semiconductor substrate having a first conductivity type, a well region in the semiconductor substrate on which the drain region is disposed, the well region having the first conductivity type, a buried isolation layer in the semiconductor substrate extending across the well region, the buried isolation layer having the first conductivity type, a reduced surface field (RESURF) region disposed between the well region and the buried isolation layer, the RESURF region having a second conductivity type, and a plug region in the semiconductor substrate extending from the surface of the substrate to the RESURF region, the plug region having the second conductivity type.

Abstract: By providing a novel bipolar device design implementation, a standard CMOS process can be used unchanged to fabricate useful bipolar transistors and other bipolar devices having adjustable properties by partially blocking the P or N well doping used for the transistor base. This provides a hump-shaped base region with an adjustable base width, thereby achieving, for example, higher gain than can be obtained with the unmodified CMOS process alone. By further partially blocking the source/drain doping step used to form the emitter of the bipolar transistor, the emitter shape and effective base width can be further varied to provide additional control over the bipolar device properties. The embodiments thus include prescribed modifications to the masks associated with the bipolar device that are configured to obtain desired device properties. The CMOS process steps and flow are otherwise unaltered and no additional process steps are required.