A semiconductor device and method of forming the same including, in one embodiment, a semiconductor die formed with a plurality of laterally diffused metal oxide semiconductor (LDMOS) cells. The semiconductor device also includes a redistribution layer electrically coupled to the plurality of LDMOS cells and a plurality of metallic pillars distributed over and electrically coupled to the redistribution layer.

A semiconductor device includes a plurality of lines disposed on a semiconductor substrate, and remaining line patterns disposed spaced apart from the lines on extensions from the lines. The lines include first end-portions adjacent to the remaining line patterns. The remaining line patterns include second end-portions adjacent to the lines. The first end-portions and second end-portions are formed to have mirror symmetry with respect to each other.

Semiconductor device structures and related fabrication methods are provided. An exemplary semiconductor device structure includes a body well region having a first conductivity type, a drift region and a source region each having a second conductivity type, where a channel portion of the body well region resides laterally between the source region and a first portion of the drift region that is adjacent to the channel portion. A gate structure overlies the channel portion and the adjacent portion of the drift region. A portion of the gate structure overlying the channel portion proximate the source region has the second conductivity type. Another portion of the gate structure that overlies the adjacent portion of the drift region has a different doping, and overlaps at least a portion of the channel portion, with the threshold voltage associated with the gate structure being influenced by the amount of overlap.

A semiconductor device can be reduced in size. The semiconductor device has a first conductivity type p type well layer extending in the X direction of the main surface of a semiconductor substrate; a reference potential wire coupled with the p type well layer, and extending in the X direction; first and second active regions arranged on the opposite sides of the reference potential wire in the Y direction; and a gate electrode layer extending in the Y direction in such a manner as to cross with the first and second active regions. Then, the gate electrode layer has a first gate electrode of a second conductivity type at the crossing part with the first active region, a second gate electrode of the second conductivity type at the crossing part with the second active region, and a non-doped electrode between the first gate electrode and the second gate electrode.

A semiconductor structure includes an isolation structure, a gate stack, a spacer and a patterned resist protective oxide. The isolation structure is formed in a semiconductor substrate, and electrically isolates device regions of the semiconductor substrate. The gate stack is located on the isolation structure. The spacer is formed along a sidewall of the gate stack on the isolation structure. The patterned resist protective oxide is located on the isolation structure and covers a sidewall of the spacer such that the spacer is interposed between the patterned resist protective oxide and the gate stack.

A method of forming a contact structure of a gate structure is provided. In the method, an oxidation layer and a first sidewall layer disposed between a first metal gate and a second metal gate are etched to expose an underlying silicon substrate. A silicide portion defined by a contact profile is deposited in the exposed portion of the silicon substrate. A second sidewall layer substantially covers the first sidewall layer and at least partially covering the silicide portion is formed after depositing the silicide portion. A metal glue layer is deposited around the first metal gate and the second metal gate defining a trench above the silicide portion. A metal plug is deposited within the trench.

An integrated circuit device includes a substrate provided with a fin-type active region which is disposed at a first surface of the substrate, a plurality of nanosheets disposed on a top surface of the fin-type active region and separated from the top surface of the fin-type active region, a gate line disposed on the fin-type active region, the gate line surrounding each of the plurality of nanosheets, a source/drain region disposed on the fin-type active region, a sidewall of the source/drain region being adjacent to the gate line and in contact with the plurality of nanosheets, a backside contact extending from a second surface of the substrate toward a lower portion of the source/drain region, and a high-concentration doped layer disposed in the lower portion of the source/drain region. The high-concentration doped layer has a dopant concentration greater than a dopant concentration of the source/drain region.

Various embodiments of the present disclosure are directed towards a semiconductor device. The semiconductor device comprises a source region and a drain region in a substrate and laterally spaced. A gate stack is over the substrate and between the source region and the drain region. The drain region includes two or more first doped regions having a first doping type in the substrate. The drain region further includes one or more second doped regions in the substrate. The first doped regions have a greater concentration of first doping type dopants than the second doped regions, and each of the second doped regions is disposed laterally between two neighboring first doped regions.

The present disclosure relates to semiconductor structures and, more particularly, to field effect transistors and methods of manufacture. The structure includes: at least one gate structure comprising source/drain regions; and at least one isolation structure perpendicular to the at least one gate structure and within the source/drain regions.

A transistor includes a first active region and a second active region separated by a semiconductor channel, a gate stack structure including a gate dielectric and a gate electrode overlying the semiconductor channel, a gate contact via structure overlying and electrically connected to the gate electrode and having a top surface located in a first horizontal plane, a first active-region contact via structure overlying and electrically connected to the first active region, and having a top surface located within a second horizontal plane that underlies the first horizontal plane, a first connection line structure contacting a top surface of the first active-region contact via structure, and a first connection via structure contacting a top surface of the first connection line structure and having a top surface within the first horizontal plane.