Abstract: A method of forming a LDMOS with a self-aligned P+ implant and LVPW region at the source side and the resulting device are provided. Embodiments include forming a DNWELL in a p-sub; forming a PWHV in the DNWELL; forming an NW in the DNWELL; forming a LVPW in the PWHV; forming STI structures through the LVPW and through the DNWELL and NW, respectively; forming a gate over the PWHV; forming a first and a second P+ implant in the LVPW, an edge of the second P+ implant aligned with an edge of the gate; forming a first N+ implant in the LVPW between the first STI structure and the second P+ implant and a second N+ in the NW adjacent to the second STI structure; and forming contacts over the first and second P+ and N+ implants, respectively, and an electrical contact over the second N+ implant.

Abstract: A method of forming a LDMOS with a self-aligned P+ implant and LVPW region at the source side and the resulting device are provided. Embodiments include forming a DNWELL in a p-sub; forming a PWHV in the DNWELL; forming an NW in the DNWELL; forming a LVPW in the PWHV; forming STI structures through the LVPW and through the DNWELL and NW, respectively; forming a gate over the PWHV; forming a first and a second P+ implant in the LVPW, an edge of the second P+ implant aligned with an edge of the gate; forming a first N+ implant in the LVPW between the first STI structure and the second P+ implant and a second N+ in the NW adjacent to the second STI structure; and forming contacts over the first and second P+ and N+ implants, respectively, and an electrical contact over the second N+ implant.

Abstract: An area-efficient, low voltage ESD protection device (200) is provided for protecting low voltage pins (229, 230) against ESD events by using one or more stacked low voltage NPN bipolar junction transistors, each formed in a p-type material with an N+ collector region (216) and P+ base region (218) formed on opposite sides of an N+ emitter region (217) with separate halo extension regions (220-222) formed around at least the collector and emitter regions to improve the second trigger or breakdown current (It2) and set the snapback voltage (Vsb) and triggering voltage (Vt1) at the desired level.

Abstract: A method of forming a LDMOS with a self-aligned P+ implant and LVPW region at the source side and the resulting device are provided. Embodiments include forming a DNWELL in a p-sub; forming a PWHV in the DNWELL; forming an NW in the DNWELL; forming a LVPW in the PWHV; forming STI structures through the LVPW and through the DNWELL and NW, respectively; forming a gate over the PWHV; forming a first and a second P+ implant in the LVPW, an edge of the second P+ implant aligned with an edge of the gate; forming a first N+ implant in the LVPW between the first STI structure and the second P+ implant and a second N+ in the NW adjacent to the second STI structure; and forming contacts over the first and second P+ and N+ implants, respectively, and an electrical contact over the second N+ implant.

Abstract: The present disclosure generally relates to semiconductor structures and, more particularly, to electrostatic discharge protective structures and methods of manufacture. The structure includes: an epitaxial layer comprising a first region, a second region and a third region; a plurality of gate structures connecting the first region to the second region and the second region to the third region; and a plurality of terminals connected to the first region and the third region and the gate structures.

Abstract: An electrostatic discharge protection clamp includes a substrate and a first electrostatic discharge protection device over the substrate. The first electrostatic discharge protection device includes a buried layer over the substrate. The buried layer has a first region having a first doping concentration and a second region having a second doping concentration. The first doping concentration is greater than the second doping concentration. The first electrostatic discharge protection device includes a first transistor over the buried layer. The first transistor has an emitter coupled to a first cathode terminal of the electrostatic discharge protection clamp. The first electrostatic discharge protection device includes a second transistor over the buried layer. The second transistor has an emitter coupled to a first anode terminal of the electrostatic discharge protection clamp. A collector of the first transistor and a collector of the second transistor are over the first region of the buried layer.

Abstract: Methods of forming a high voltage ESD GGNMOS using embedded gradual PN junction in the source region and the resulting devices are provided. Embodiments include a device having a substrate including a device region with an ESD protection circuit; a gate over the device region; a source region in the device region having a N+ implant and a P+ implant laterally separated on a first side of the gate; and a drain region in the device region on a second side of the gate, opposite the first.

Abstract: Methods of forming a high voltage ESD GGNMOS using embedded gradual PN junction in the source region and the resulting devices are provided. Embodiments include a device having a substrate including a device region with an ESD protection circuit; a gate over the device region; a source region in the device region having a N+ implant and a P+ implant laterally separated on a first side of the gate; and a drain region in the device region on a second side of the gate, opposite the first.

Abstract: A method of forming a LDMOS with a self-aligned P+ implant and LVPW region at the source side and the resulting device are provided. Embodiments include forming a DNWELL in a p-sub; forming a PWHV in the DNWELL; forming an NW in the DNWELL; forming a LVPW in the PWHV; forming STI structures through the LVPW and through the DNWELL and NW, respectively; forming a gate over the PWHV; forming a first and a second P+ implant in the LVPW, an edge of the second P+ implant aligned with an edge of the gate; forming a first N+ implant in the LVPW between the first STI structure and the second P+ implant and a second N+ in the NW adjacent to the second STI structure; and forming contacts over the first and second P+ and N+ implants, respectively, and an electrical contact over the second N+ implant.

Abstract: A method of forming a HV lateral PNP BJT with a pulled back isolation structure and a polysilicon gate covering a part of the NW+HVNDDD base region and a part of the collector extension (HVPDDD) and the resulting device are provided. Embodiments include forming a DVNWELL in a portion of a p-sub; forming a HVPDDD in a portion of the DVNWELL; forming a LVPW in a portion of the HVPDDD; forming a first and a second NW laterally separated in a portion of the DVNWELL, the first and second NW being laterally separated from the HVPDDD; forming a N+ base, a P+ emitter, and a P+ collector in an upper portion of the first and second NW and LVPW, respectively; forming a STI structure between the P+ emitter and P+ collector in a portion of the DVNWELL, HVPDDD, and LVPW, respectively; and forming a SAB layer over the STI structure.

Abstract: Integrated circuits and methods of producing such integrated circuits are provided. In an exemplary embodiment, an integrated circuit includes a deep well with a drain well overlying the deep well. A first source well also overlies the deep well, where the first source well includes a first source well concentration of conductivity determining impurities. A second source well overlies the first source well, where the second source well includes a second concentration of conductivity determining impurities that is higher than the first source well concentration. A drain overlies the drain well and a source overlies the second source well. A channel is defined between the source and the drain and a gate overlies the channel.

Abstract: An ESD protection device is fabricated in a semiconductor substrate that includes a semiconductor layer having a first conductivity type. A first well implantation procedure implants dopant of a second conductivity type in the semiconductor layer to form inner and outer sinker regions. The inner sinker region is configured to establish a common collector region of first and second bipolar transistor devices. A second well implantation procedure implants dopant of the first conductivity type in the semiconductor layer to form respective base regions of the first and second bipolar transistor devices. Conduction of the first bipolar transistor device is triggered by breakdown between the inner sinker region and the base region of the first bipolar transistor device. Conduction of the second bipolar transistor device is triggered by breakdown between the outer sinker region and the base region of the second bipolar transistor device.

Abstract: An electrostatic discharge protection clamp includes a substrate and a first electrostatic discharge protection device over the substrate. The first electrostatic discharge protection device includes a buried layer over the substrate. The buried layer has a first region having a first doping concentration and a second region having a second doping concentration. The first doping concentration is greater than the second doping concentration. The first electrostatic discharge protection device includes a first transistor over the buried layer. The first transistor has an emitter coupled to a first cathode terminal of the electrostatic discharge protection clamp. The first electrostatic discharge protection device includes a second transistor over the buried layer. The second transistor has an emitter coupled to a first anode terminal of the electrostatic discharge protection clamp. A collector of the first transistor and a collector of the second transistor are over the first region of the buried layer.

Abstract: An electrostatic discharge protection clamp includes a substrate and a first electrostatic discharge protection device over the substrate. The first electrostatic discharge protection device includes a buried layer over the substrate. The buried layer has a first region having a first doping concentration and a second region having a second doping concentration. The first doping concentration is greater than the second doping concentration. The first electrostatic discharge protection device includes a first transistor over the buried layer. The first transistor has an emitter coupled to a first cathode terminal of the electrostatic discharge protection clamp. The first electrostatic discharge protection device includes a second transistor over the buried layer. The second transistor has an emitter coupled to a first anode terminal of the electrostatic discharge protection clamp. A collector of the first transistor and a collector of the second transistor are over the first region of the buried layer.

Abstract: An electrostatic discharge (ESD) protection device includes a semiconductor substrate, a base region in the semiconductor substrate and having a first conductivity type, an emitter region in the base region and having a second conductivity type, a collector region in the semiconductor substrate, spaced from the base region, and having the second conductivity type, a breakdown trigger region having the second conductivity type, disposed laterally between the base region and the collector region to define a junction across which breakdown occurs to trigger the ESD protection device to shunt ESD discharge current, and a gate structure supported by the semiconductor substrate over the breakdown trigger region and electrically tied to the base region and the emitter region. The lateral width of the breakdown trigger region is configured to establish a voltage level at which the breakdown occurs.

Abstract: Protection device structures and related fabrication methods are provided. An exemplary semiconductor protection device includes a base region of semiconductor material having a first conductivity type, an emitter region within the base region having the opposite conductivity type, and a collector region of semiconductor material having the second conductivity type, wherein at least a portion of the base region resides between the emitter region and the collector region. A depth of the collector region is greater than a depth of the emitter region and less than or equal to a depth of the base region such that a distance between a lateral boundary of the emitter region and a proximal lateral boundary of the collector region is greater than zero and the collector region does not overlap or otherwise underlie the emitter region.

Abstract: Protection device structures and related fabrication methods are provided. An exemplary semiconductor protection device includes a first base region of semiconductor material having a first conductivity type, a second base region of semiconductor material having the first conductivity type and a dopant concentration that is less than the first base region, a third base region of semiconductor material having the first conductivity type and a dopant concentration that is greater than the second base region, an emitter region of semiconductor material having a second conductivity type opposite the first conductivity type within the first base region, and a collector region of semiconductor material having the second conductivity type. At least a portion of the second base region resides between the third base region and the first base region and at least a portion of the first base region resides between the emitter region and the collector region.

Abstract: ESD protection device structures and related fabrication methods are provided. An exemplary semiconductor protection device includes a first base well region having a first conductivity type, a collector region of the opposite conductivity type, and a second base well region having a dopant concentration greater than the first base well region, and a portion of the second base well region is disposed between the first base well region and the collector region. A third base well region with a different dopant concentration is disposed between the collector region and the second base well region. At least a portion of the first base well region is disposed between a base contact region and an emitter region within the second base well region.

Abstract: ESD protection device structures and related fabrication methods are provided. An exemplary semiconductor protection device includes a first base well region having a first conductivity type, a collector region of the opposite conductivity type, and a second base well region having a dopant concentration greater than the first base well region, and a portion of the second base well region is disposed between the first base well region and the collector region. A third base well region with a different dopant concentration is disposed between the collector region and the second base well region. At least a portion of the first base well region is disposed between a base contact region and an emitter region within the second base well region.

Abstract: An ESD protection device is fabricated in a semiconductor substrate that includes a semiconductor layer having a first conductivity type. A first well implantation procedure implants dopant of a second conductivity type in the semiconductor layer to form inner and outer sinker regions. The inner sinker region is configured to establish a common collector region of first and second bipolar transistor devices. A second well implantation procedure implants dopant of the first conductivity type in the semiconductor layer to form respective base regions of the first and second bipolar transistor devices. Conduction of the first bipolar transistor device is triggered by breakdown between the inner sinker region and the base region of the first bipolar transistor device. Conduction of the second bipolar transistor device is triggered by breakdown between the outer sinker region and the base region of the second bipolar transistor device.