A semiconductor device according to an embodiment includes: a first electrode; a first semiconductor region of a first conductive type provided on the first electrode; a second semiconductor region of a second conductive type provided on the first semiconductor region; a third semiconductor region of a first conductive type provided on the second semiconductor region; a gate electrode provided in the second semiconductor region via a gate insulating film; a contact portion having a first portion and a second portion; and a second electrode electrically connected to the contact portion. The first portion is aligned with the third semiconductor region and a part of the second semiconductor region, and the second portion is provided at a lower end of the first portion and has a width larger than a width of the first portion at an upper end of the third semiconductor region.

A field effect transistor includes a substrate comprising a fin structure. The field effect transistor further includes an isolation structure in the substrate. The field effect transistor further includes a source/drain (S/D) recess cavity below a top surface of the substrate. The S/D recess cavity is between the fin structure and the isolation structure. The field effect transistor further includes a strained structure in the S/D recess cavity. The strain structure includes a lower portion. The lower portion includes a first strained layer, wherein the first strained layer is in direct contact with the isolation structure, and a dielectric layer, wherein the dielectric layer is in direct contact with the substrate, and the first strained layer is in direct contact with the dielectric layer. The strained structure further includes an upper portion comprising a second strained layer overlying the first strained layer.

LDMOS devices are disclosed. An LDMOS device includes at least one drift region disposed in a portion of a semiconductor substrate; at least one isolation structure at a surface of the semiconductor substrate; a D-well region positioned adjacent a portion of the at least one drift region, and an intersection of the drift region and the D-well region forming a junction between first and second conductivity types; a gate structure disposed over the semiconductor substrate; a source contact region disposed on the surface of the D-well region; a drain contact region disposed adjacent the isolation structure; and a double buffer region comprising a first buried layer lying beneath the D-well region and the drift region and doped to the second conductivity type and a second high voltage deep diffusion layer lying beneath the first buried layer and doped to the first conductivity type. Methods are disclosed.

A MOS transistor comprises a substrate of a first conductivity, a first region of the first conductivity formed over the substrate, a second region of the first conductivity formed in the first region, a first drain/source region of a second conductivity formed in the second region, a second drain/source region of the second conductivity and a body contact region of the first conductivity, wherein the body contact region and the first drain/source region are formed in an alternating manner from a top view.

A vertical conduction integrated electronic device including: a semiconductor body; a trench that extends through part of the semiconductor body and delimits a portion of the semiconductor body, which forms a first conduction region having a first type of conductivity and a body region having a second type of conductivity, which overlies the first conduction region; a gate region of conductive material, which extends within the trench; an insulation region of dielectric material, which extends within the trench and is arranged between the gate region and the body region; and a second conduction region, which overlies the body region. The second conduction region is formed by a conductor.

A method of forming an integrated DMOS transistor/EEPROM cell includes forming a first mask over a substrate, forming a drift implant in the substrate using the first mask to align the drift implant, simultaneously forming a first floating gate over the drift implant, and a second floating gate spaced apart from the drift implant, forming a second mask covering the second floating gate and covering a portion of the first floating gate, forming a base implant in the substrate using an edge of the first floating gate to self-align the base implant region, and simultaneously forming a first control gate over the first floating gate and a second control gate over the second floating gate. The first floating gate, first control gate, drift implant, and base implant form components of the DMOS transistor, and the second floating gate and second control gate form components of the EEPROM cell.

Performances of a semiconductor device are improved. The semiconductor device has: a gate electrode formed on an SOI layer of an SOI substrate via a gate insulating film having a charge storage film therein; an n-type semiconductor region and a p-type semiconductor region respectively formed on SOI layers on both sides of the gate electrode. A memory cell MC serving as a non-volatile memory cell is formed of the gate insulating film, the gate electrode, the n-type semiconductor region and the p-type semiconductor region.

In one aspect, a double-diffused metal oxide semiconductor (DMOS) includes a region of a semiconductor having a first region of a semiconductor having a first-type dopant, a first well having a second-type dopant, a dielectric within the first well, the dielectric having a bottom surface and a top surface opposite the bottom surface, a gate disposed on the top surface of the dielectric. The gate, the dielectric and the first well are configured to form a first reduced surface field (RESURF). The bottom surface of the dielectric has a first portion and a second portion, and the first portion of the bottom surface of the dielectric is closer to the top surface of the dielectric than the second portion of the bottom surface of the dielectric.

Disclosed herein are Lateral Diffused Metal Oxide Semiconductor (LDMOS) device and trench isolation related devices, methods, and techniques. In one illustration, a doped region is formed within a semiconductor substrate. A trench isolation region is formed within the doped region. The doped region and the trench isolation region are part of a Lateral Diffused Metal Oxide Semiconductor (LDMOS) device. The trench isolation region or an interface between the trench isolation region and the doped region is configured to reduce low frequency noise in the LDMOS device.

A field effect transistor includes a substrate comprising a fin structure. The field effect transistor further includes an isolation structure in the substrate. The field effect transistor further includes a source/drain (S/D) recess cavity below a top surface of the substrate. The S/D recess cavity is between the fin structure and the isolation structure. The field effect transistor further includes a strained structure in the S/D recess cavity. The strain structure includes a lower portion. The lower portion includes a first strained layer, wherein the first strained layer is in direct contact with the isolation structure, and a dielectric layer, wherein the dielectric layer is in direct contact with the substrate, and the first strained layer is in direct contact with the dielectric layer. The strained structure further includes an upper portion comprising a second strained layer overlying the first strained layer.