Abstract: A method forms an integrated circuit, by steps including, in a first implant, forming in a semiconductor substrate a first and second region of a first semiconductor type, each of the first and second region having a first dopant concentration; in a second implant, forming in the semiconductor substrate a third and fourth region of the first semiconductor type, the third region at least partially overlapping the first region and the fourth region at least partially overlapping the second region, each of the third and fourth region having a second dopant concentration different than the first dopant concentration; forming a transistor source within the first and third regions; and forming one of a diode anode or a diode cathode in the second and fourth regions.

Abstract: Described examples include an integrated circuit having a transistor with a first gate on a first gate insulating layer. The transistor also has second gate separated from the first gate by a gate gap. The integrated circuit also includes a channel well at the gate gap extending under the first gate and the second gate. The transistor has a first source in the channel adjacent to an edge of the first gate. The transistor having a second source formed in the channel adjacent to an edge of the second gate separated from the first source by a channel gap. The transistor has at least one back-gate contact, the at least one back-gate contact separated from the first gate by a first back-gate contact gap and separated from the second gate by a second back-gate contact gap.

Abstract: A method of manufacturing an integrated circuit includes forming first and second false collector regions of a first conductivity type adjacent to a surface of an epitaxial layer of semiconductor material. The first false collector region is located laterally on a first side of a base region. The base region is formed within the epitaxial layer and has a second conductivity type. The second false collector region is located laterally on a second side of the base region. The second side is opposite the first side of the base region. The base region is a base of a parasitic bipolar junction in an isolation region of an active semiconductor device.

Abstract: Semiconductor devices including a high-k field relief dielectric structure are described. The microelectronic device comprises a substrate including a body region and a drain drift region on the substrate, a gate dielectric layer extending over the body region and the drift region, a drain drift trench is formed by removal of silicon dioxide from a LOCOS silicon region, a high-k field relief dielectric structure laterally abutting the gate dielectric layer at a location in the drift region, and a gate electrode on the gate dielectric layer and the field relief dielectric layer. Increasing the dielectric constant of the field relief dielectric structure may improve channel hot carrier performance, improve breakdown voltage, and reduce the specific on resistance. A drain drift trench formed in a trench left after removal of silicon dioxide in a LOCOS region provides improved trench depth uniformity.

Abstract: A microelectronic device includes a doped region of semiconductor material having a first region and an opposite second region. The microelectronic device is configured to provide a first operational potential at the first region and to provide a second operational potential at the second region. The microelectronic device includes field plate segments in trenches extending into the doped region. Each field plate segment is separated from the semiconductor material by a trench liner of dielectric material. The microelectronic device further includes circuitry electrically connected to each of the field plate segments. The circuitry is configured to apply bias potentials to the field plate segments. The bias potentials are monotonic with respect to distances of the field plate segments from the first region of the doped region.

Abstract: A microelectronic device including an analog MOS transistor. The analog transistor has a body well having a first conductivity type in a semiconductor material of a substrate of the microelectronic device. The body well extends deeper in the substrate than a field relief dielectric layer at the top surface of the semiconductor material. The analog transistor has a drain well and a source well having a second, opposite, conductivity type in the semiconductor material, both contacting the body well. The drain well and the source well extend deeper in the substrate than the field relief dielectric layer. The analog transistor has a gate on a gate dielectric layer over the body well. The drain well and the source well extend partway under the gate at the top surface of the semiconductor material.

Abstract: A microelectronic device including an analog MOS transistor. The analog transistor has a body well having a first conductivity type in a semiconductor material of a substrate of the microelectronic device. The body well extends deeper in the substrate than a field relief dielectric layer at the top surface of the semiconductor material. The analog transistor has a drain well and a source well having a second, opposite, conductivity type in the semiconductor material, both contacting the body well. The drain well and the source well extend deeper in the substrate than the field relief dielectric layer. The analog transistor has a gate on a gate dielectric layer over the body well. The drain well and the source well extend partway under the gate at the top surface of the semiconductor material.

Abstract: An integrated circuit chip and a method of fabricating the IC chip to include a transistor having a thick gate oxide in combination with STI. The method provides a wafer for which a source region location, a drain contact region location, an extended drain region location and a gate region location have been defined and forms an STI structure overlying the extended drain region location. After growing a gate oxide layer over the gate region location and a portion of the extended drain region location, the method forms a gate structure on the gate oxide layer, the gate structure having a gap overlying the intersection of an edge of the STI structure with the gate oxide layer.

Abstract: A semiconductor device including drain extended metal oxide semiconductor field effect transistor (MOSFET) includes a source region and a drain region each having a first dopant type spaced apart along a surface of a semiconductor material having a second opposite conductivity type. A gate electrode over the semiconductor material surface between the source region and the drain region. A diffusion suppression implant region in the semiconductor material extends from the source region under the gate electrode. The diffusion suppression implant region includes a body region having the second opposite conductivity type and comprises at least one of carbon, nitrogen, and fluorine.

Abstract: A method includes implanting dopant of a first conductivity type into an epitaxial layer of semiconductor material to form first and second false collector regions adjacent to the surface of the epitaxial layer. The first false collector region is located laterally on a first side of a base region. The base region is formed within the epitaxial layer from dopant of a second conductivity type that is opposite the first conductivity type. The second false collector region is located laterally on a second side of the base region. The second side is opposite the first side of the base region. The base region is a base of a parasitic bipolar junction in an isolation region of an active semiconductor device.

Abstract: Breakdown diodes and methods of making the same are described. Such a breakdown diode can be fabricated in a semiconductor substrate and have a junction configured to breakdown under a target reverse bias applied across the junctions. The junction is located below the surface of the substrate by a distance suitable for ameliorating mechanical stress impact to the reverse bias breakdown voltage of the junction. Moreover, the junction is located away from an interface causing noise issues.

Abstract: A semiconductor device including drain extended metal oxide semiconductor field effect transistor (MOSFET) includes a source region and a drain region each having a first dopant type spaced apart along a surface of a semiconductor material having a second opposite conductivity type. A gate electrode over the semiconductor material surface between the source region and the drain region. A diffusion suppression implant region in the semiconductor material extends from the source region under the gate electrode. The diffusion suppression implant region includes a body region having the second opposite conductivity type and comprises at least one of carbon, nitrogen, and fluorine.

Abstract: A method includes implanting dopant of a first conductivity type into an epitaxial layer of semiconductor material to form first and second false collector regions adjacent to the surface of the epitaxial layer. The first false collector region is located laterally on a first side of a base region. The base region is formed within the epitaxial layer from dopant of a second conductivity type that is opposite the first conductivity type. The second false collector region is located laterally on a second side of the base region. The second side is opposite the first side of the base region. The base region is a base of a parasitic bipolar junction in an isolation region of an active semiconductor device.

Abstract: An integrated circuit includes a source region and a drain region spaced apart and extending into a semiconductor layer. A gate electrode extends between the source and the drain regions, and a dielectric layer is between the gate electrode and the semiconductor layer. The dielectric layer includes a first portion having a first thickness and a second portion having a second greater second thickness and a lateral perimeter surrounding the source region. The lateral perimeter includes a first edge having a first linear segment extending between the source region and the drain region along a first direction and a second edge having a second linear segment extending over the semiconductor layer along a different second direction. A fillet of the second portion connects the first linear segment and the second linear segment of the lateral perimeter.

Abstract: Active semiconductor devices in an integrated circuit are provided lateral electrical isolation by surrounding narrow deep trench isolation regions that are merged at shared portions of the narrow deep trench isolation regions. A wide deep trench isolation region laterally surrounds the merged narrow deep trench isolation regions.

Abstract: A semiconductor device which includes two or more integrated deep trench features configured as a Zener diode. The Zener diode includes a plurality of deep trenches extending into semiconductor material of the substrate and a dielectric deep trench liner that includes a dielectric material. The deep trench further includes a doped sheath contacting the deep trench liner and an electrically conductive deep trench filler material within the deep trench. The doped sheath of adjacent deep trenches overlap and form a region of higher doping concentration which sets the breakdown voltage of the Zener diode. The Zener diode can be used as a triggering diode to limit the voltage on other components in a semiconductor device.

Abstract: A microelectronic device includes a doped region of semiconductor material having a first region and an opposite second region. The microelectronic device is configured to provide a first operational potential at the first region and to provide a second operational potential at the second region. The microelectronic device includes field plate segments in trenches extending into the doped region. Each field plate segment is separated from the semiconductor material by a trench liner of dielectric material. The microelectronic device further includes circuitry electrically connected to each of the field plate segments. The circuitry is configured to apply bias potentials to the field plate segments. The bias potentials are monotonic with respect to distances of the field plate segments from the first region of the doped region.

Abstract: An electronic device includes a semiconductor substrate and a semiconductor surface layer having a first conductivity type, as well as a buried layer, a deep trench structure and a shallow trench isolation structure, the semiconductor surface layer over the semiconductor substrate and having a top surface, the buried layer having an opposite second conductivity type between the semiconductor surface layer and the semiconductor substrate, the deep trench structure including a trench that extends through the semiconductor surface layer and into the buried layer, a dielectric liner on a sidewall of the trench from the semiconductor surface layer to the buried layer, and polysilicon that extends on the dielectric liner and fills the trench to the side of the semiconductor surface layer, the shallow trench isolation structure extends into the semiconductor surface layer, and the shallow trench isolation structure in contact with the deep trench structure.

Abstract: An electronic device includes a semiconductor substrate and a semiconductor surface layer having a first conductivity type, the semiconductor surface layer over the semiconductor substrate and having a top surface, a buried layer having an opposite second conductivity type between the semiconductor surface layer and the semiconductor substrate, a dielectric isolation layer that extends over and into the semiconductor surface layer, a deep trench structure that extends through the dielectric isolation layer into the semiconductor surface layer, and a silicide blocking layer on a top surface of the deep trench structure.

Abstract: A semiconductor device which includes two or more integrated deep trench features configured as a Zener diode. The Zener diode includes a plurality of deep trenches extending into semiconductor material of the substrate and a dielectric deep trench liner that includes a dielectric material. The deep trench further includes a doped sheath contacting the deep trench liner and an electrically conductive deep trench filler material within the deep trench. The doped sheath of adjacent deep trenches overlap and form a region of higher doping concentration which sets the breakdown voltage of the Zener diode. The Zener diode can be used as a triggering diode to limit the voltage on other components in a semiconductor device.