Abstract: A method of forming a device includes forming a buried well region of a first dopant type in a substrate. A well region of the first dopant type is formed over the buried well region. A first well region of a second dopant type is formed between the well region of the first dopant type and the buried well region of the first dopant type. A second well region of the second dopant type is formed in the well region of the first dopant type. An isolation structure is formed at least partially in the well region of the first dopant type. A first gate electrode is formed over the isolation structure and the second well region of the second dopant type.

Abstract: Provided is a semiconductor device. The semiconductor device includes a resistor and a voltage protection device. The resistor has a spiral shape. The resistor has a first portion and a second portion. The voltage protection device includes a first doped region that is electrically coupled to the first portion of the resistor. The voltage protection device includes a second doped region that is electrically coupled to the second portion of the resistor. The first and second doped regions have opposite doping polarities.

Abstract: A semiconductor device includes a buried layer in a substrate, the buried layer having a first dopant type. The semiconductor device further includes a first layer over the buried layer, the first layer having the first dopant type. The semiconductor device further includes at least one first well in the first layer, the at least one first well having a second dopant type. The semiconductor device further includes an implantation region in a sidewall of the first layer, the implantation region having the second dopant type, wherein the implantation region is below the at least one first well. The semiconductor device further includes a metal electrode extending from the buried layer to a drain contact, wherein the metal electrode is insulated from the first layer and the at least one first well by an insulation layer.

Abstract: A device includes a semiconductor layer of a first conductivity type, and a first and a second body region over the semiconductor layer, wherein the first and the second body regions are of a second conductivity type opposite the first conductivity type. A doped semiconductor region of the first conductivity type is disposed between and contacting the first and the second body regions. A gate dielectric layer is disposed over the first and the second body regions and the doped semiconductor region. A first and a second gate electrode are disposed over the gate dielectric layer, and overlapping the first and the second body regions, respectively. The first and the second gate electrodes are physically separated from each other by a space, and are electrically interconnected. The space between the first and the second gate electrodes overlaps the doped semiconductor region. The device further includes a MOS containing device.

Abstract: A device includes a trench extending into a semiconductor region and having a first conductivity type, and a conductive field plate in the trench. A first dielectric layer separates a bottom and sidewalls of the field plate from the semiconductor region. A main gate is disposed in the trench and overlapping the field plate. A second dielectric layer is disposed between and separating the main gate and the field plate from each other. A Doped Drain (DD) region of the first conductivity type is under the second dielectric layer and having an edge portion overlapping the DD region. A body region includes a first portion at a same level as a portion of the main gate, and a second portion contacting the DD region, wherein the body region is of a second conductivity type opposite the first conductivity type. A MOS-containing device is at a surface of the semiconductor region.

Abstract: A device includes a semiconductor region of a first conductivity type, a trench extending into the semiconductor region, and a conductive field plate in the trench. A first dielectric layer separates a bottom and sidewalls of the field plate from the semiconductor region. A main gate is disposed in the trench and overlapping the field plate. A second dielectric layer is disposed between and separating the main gate and the field plate from each other. A Doped Drain (DD) region of the first conductivity type is under the second dielectric layer, wherein an edge portion of the main gate overlaps the DD region. A body region includes a first portion at a same level as a portion of the main gate, and a second portion at a same level as, and contacting, the DD region, wherein the body region is of a second conductivity type opposite the first conductivity type.

Abstract: An apparatus comprises a buried layer over a substrate, an epitaxial layer over the buried layer, a first trench extending through the epitaxial layer and partially through the buried layer, a second trench extending through the epitaxial layer and partially through the buried layer, a dielectric layer in a bottom portion of the first trench, a first gate region in an upper portion of the first trench, a second gate region in the second trench, wherein the second gate region is electrically coupled to the first gate region, a drain region in the epitaxial layer and a source region on an opposite side of the first trench from the drain region.

Abstract: A method of forming a manufacture includes forming a trench in a doped layer. The trench has an upper portion and a lower portion, and a width of the upper portion is greater than that of the lower portion. A first insulating layer is formed along sidewalls of the lower portion of the trench and a bottom surface of the trench. A gate dielectric layer is formed along sidewalls of the upper portion of the trench. A first conductive feature is formed along sidewalls of the gate dielectric layer. A second insulating layer covering the first conductive feature and the first insulating layer is formed, and a second conductive feature is formed along sidewalls of the second insulating layer and a bottom surface of the second insulating layer.

Abstract: An integrated circuit comprises a plurality of lateral devices and quasi vertical devices formed in a same semiconductor die. The quasi vertical devices include two trenches. A first trench is formed between a first drain/source region and a second drain/source region. The first trench comprises a dielectric layer formed in a bottom portion of the first trench and a gate region formed in an upper portion of the first trench. A second trench is formed on an opposite side of the second drain/source region from the first trench. The second trench is coupled between the second drain/source region and a buried layer, wherein the second trench is of a same depth as the first trench.

Abstract: Provided is a high voltage semiconductor device. The semiconductor device includes a doped well located in a substrate that is oppositely doped. The semiconductor device includes a dielectric structure located on the doped well. A portion of the doped well adjacent the dielectric structure has a higher doping concentration than a remaining portion of the doped well. The semiconductor device includes an elongate polysilicon structure located on the dielectric structure. The elongate polysilicon structure has a length L. The portion of the doped well adjacent the dielectric structure is electrically coupled to a segment of the elongate polysilicon structure that is located away from a midpoint of the elongate polysilicon structure by a predetermined distance that is measured along the elongate polysilicon structure. The predetermined distance is in a range from about 0*L to about 0.1*L.

Abstract: A device includes a semiconductor layer of a first conductivity type, and a first and a second body region over the semiconductor layer, wherein the first and the second body regions are of a second conductivity type opposite the first conductivity type. A doped semiconductor region of the first conductivity type is disposed between and contacting the first and the second body regions. A gate dielectric layer is disposed over the first and the second body regions and the doped semiconductor region. A first and a second gate electrode are disposed over the gate dielectric layer, and overlapping the first and the second body regions, respectively. The first and the second gate electrodes are physically separated from each other by a space, and are electrically interconnected. The space between the first and the second gate electrodes overlaps the doped semiconductor region. The device further includes a MOS containing device.

Abstract: A semiconductor device includes a buried layer in a substrate, the buried layer having a first dopant type. The semiconductor device further includes a first layer over the buried layer, the first layer having the first dopant type. The semiconductor device further includes at least one first well in the first layer, the at least one first well having a second dopant type. The semiconductor device further includes an implantation region in a sidewall of the first layer, the implantation region having the second dopant type, wherein the implantation region is below the at least one first well. The semiconductor device further includes a metal electrode extending from the buried layer to a drain contact, wherein the metal electrode is insulated from the first layer and the at least one first well by an insulation layer.

Abstract: Power Metal-Oxide-Semiconductor Field-Effect Transistors (MOSFETs) and methods of forming the same are provided. A power MOSFET may comprise a first drift region formed at a side of a gate electrode, and a second drift region beneath the gate electrode, adjacent to the first drift region, with a depth less than a depth of the first drift region so that the first drift region and the second drift region together form a stepwise shape. A sum of a depth of the second drift region, a depth of the gate dielectric, and a depth of the gate electrode may be of substantially a same value as a depth of the first drift region. The first drift region and the second drift region may be formed at the same time, using the gate electrode as a part of the implanting mask.

Abstract: A method comprises forming a first trench and a second trench, depositing a dielectric material in a lower portion of the first trench, depositing a gate electrode material in the second trench and an upper portion of the first trench, forming a first N+ region and a second N+ region through an ion implantation process, wherein the first N+ region and the second N+ region are on opposite sides of the first trench and forming an accumulation layer along a sidewall of the second trench.

Abstract: A semiconductor device configured to provide high heat dissipation and improve breakdown voltage comprises a substrate, a buried oxide layer over the substrate, a buried n+ region in the substrate below the buried oxide layer, and an epitaxial layer over the buried oxide layer. The epitaxial layer comprises a p-well, an n-well, and a drift region between the p-well and the n-well. The semiconductor device also comprises a source contact, a first electrode electrically connecting the source contact to the p-well, and a gate over a portion of the p-well and a portion of the drift region. The semiconductor device further comprises a drain contact, and a second electrode extending from the drain contact through the n-well and through the buried oxide layer to the buried n+ region. The second electrode electrically connects the drain contact to the n-well and to the buried n+ region.

Abstract: A semiconductor device configured to provide increased current gain comprises a semiconductor substrate having a first conductivity type. The device also comprises a first semiconductor region having a second conductivity type. The device further comprises a second semiconductor region in the first semiconductor region to having the first conductivity type. The device additionally comprises a third semiconductor region in the first semiconductor region having the second conductivity type. The device also comprises a fourth semiconductor region outside the first semiconductor region having the first conductivity type. The device further comprises a fifth semiconductor region outside the first semiconductor region adjacent the fourth semiconductor region and having the second conductivity type. The device additionally comprises a first electrode electrically connected to the third semiconductor region.

Abstract: An integrated circuit device includes a pad layer having a body portion with a first doping type laterally adjacent to a drift region portion with a second doping type, a trench formed in the pad layer, the trench extending through an interface of the body portion and the drift region portion, a gate formed in the trench and over a top surface of the pad layer along the interface of the body portion and the drift region portion, an oxide formed in the trench on opposing sides of the gate, and a field plate embedded in the oxide on each of the opposing sides of the gate.

Abstract: A semiconductor device includes a buried layer having a first dopant type in a substrate. The semiconductor device includes a first layer having the first dopant type over the buried layer. The semiconductor device includes at least one first well of a second dopant type disposed in the first layer. The semiconductor device includes an implantation region of the second dopant type in a sidewall of the first layer, wherein the implantation region is below the at least one first well. The semiconductor device includes a first source region disposed in the at least one first well; and at least one gate disposed on top of the first well and the first layer. The semiconductor device includes a metal electrode extending from the buried layer to a drain contact, wherein the metal electrode is insulated from the first layer and the at least one first well by an insulation layer.

Abstract: A device includes a trench extending into a semiconductor region and having a first conductivity type, and a conductive field plate in the trench. A first dielectric layer separates a bottom and sidewalls of the field plate from the semiconductor region. A main gate is disposed in the trench and overlapping the field plate. A second dielectric layer is disposed between and separating the main gate and the field plate from each other. A Doped Drain (DD) region of the first conductivity type is under the second dielectric layer and having an edge portion overlapping the DD region. A body region includes a first portion at a same level as a portion of the main gate, and a second portion contacting the DD region, wherein the body region is of a second conductivity type opposite the first conductivity type. A MOS-containing device is at a surface of the semiconductor region.

Abstract: Power Metal-Oxide-Semiconductor Field-Effect Transistors (MOSFETs) and methods of forming the same are provided. A power MOSFET may comprise a first drift region formed at a side of a gate electrode, and a second drift region beneath the gate electrode, adjacent to the first drift region, with a depth less than a depth of the first drift region so that the first drift region and the second drift region together form a stepwise shape. A sum of a depth of the second drift region, a depth of the gate dielectric, and a depth of the gate electrode may be of substantially a same value as a depth of the first drift region. The first drift region and the second drift region may be formed at the same time, using the gate electrode as a part of the implanting mask.