A high voltage device includes a substrate, a first LDMOS transistor and a second LDMOS transistor disposed on the substrate. The first LDMOS transistor includes a first gate electrode disposed on the substrate. A first STI is embedded in the substrate and disposed at an edge of the first gate electrode and two first doping regions respectively disposed at one side of the first STI and one side of the first gate electrode. The second LDMOS transistor includes a second gate electrode disposed on the substrate. A second STI is embedded in the substrate and disposed at an edge of the second gate electrode. Two second doping regions are respectively disposed at one side of the second STI and one side of the second gate electrode, wherein the second STI is deeper than the first STI.

A device includes a semiconductor substrate, a doped isolation barrier disposed in the semiconductor substrate to isolate the device, a drain region disposed in the semiconductor substrate and to which a voltage is applied during operation, and a depleted well region disposed in the semiconductor substrate, and having a conductivity type in common with the doped isolation barrier and the drain region. The depleted well region is positioned between the doped isolation barrier and the drain region to electrically couple the doped isolation barrier and the drain region such that the doped isolation barrier is biased at a voltage level lower than the voltage applied to the drain region.

A semiconductor device comprises a field effect transistor in a semiconductor substrate having a first main surface. The field effect transistor comprises a source region, a drain region, a body region, and a gate electrode at the body region. The gate electrode is configured to control a conductivity of a channel formed in the body region, and the gate electrode is disposed in gate trenches. The body region is disposed along a first direction between the source region and the drain region, the first direction being parallel to the first main surface. The body region has a shape of a ridge extending along the first direction, the body region being adjacent to the source region and the drain region. The semiconductor device further comprises a source contact and a body contact, the source contact being electrically connected to a source terminal, the body contact being electrically connected to the source contact and to the body region.

A semiconductor device is provided. The semiconductor device includes a substrate including a first conductive type well region; a gate structure; a lightly-doped drain region and a lightly-doped source region disposed at two opposite sides of the gate structure; a second conductive type first doped region disposed in the lightly-doped drain region, wherein the doping concentration of the second conductive type first doped region is less than the doping concentration of the lightly-doped drain region; a heavily-doped source region disposed in the lightly-doped source region; and a heavily-doped drain region disposed in the second conductive type first doped region. The present disclosure also provides a method for manufacturing the semiconductor device.

A laterally diffused metal oxide semiconductor (LDMOS) device includes a substrate having a p-epi layer thereon, a p-body region in the p-epi layer and an ndrift (NDRIFT) region within the p-body to provide a drain extension region. A gate stack includes a gate dielectric layer over a channel region in the p-body region adjacent to and on respective sides of a junction with the NDRIFT region. A patterned gate electrode is on the gate dielectric. A DWELL region is within the p-body region. A source region is within the DWELL region, and a drain region is within the NDRIFT region. An effective channel length (Leff) for the LDMOS device is 75 nm to 150 nm which evidences a DWELL implant that utilized an edge of the gate electrode to delineate an edge of a DWELL ion implant so that the DWELL region is self-aligned to the gate electrode.

A method of fabricating a laterally diffused metal-oxide-semiconductor (LDMOS) transistor device having a bipolar transistor for electrostatic discharge (ESD) protection includes doping a substrate to form a body region of the LDMOS transistor device in the substrate, the body region having a first conductivity type, forming a doped isolating region of the LDMOS transistor device in the substrate, the doped isolating region having a second conductivity type and surrounding a device area of the LDMOS transistor device in which the body region is disposed, forming a base contact region of the bipolar transistor, the base contact region being disposed within the body region and having the first conductivity type, and doping the substrate to form an isolation contact region for the doped isolating region that defines a collector region of the bipolar transistor, to form source and drain regions of the LDMOS transistor device in the substrate, and to form an emitter region of the bipolar transistor within the body region.

A source-drain structure and method of manufacturing the same are disclosed. The source-drain structure includes a substrate containing a drain region and a source region. The drain region includes a lightly-doped ultra-shallow junction and a heavily-doped region, and a drain-substrate junction disposed in the vicinity of a junction between a side portion and a bottom portion of the lightly-doped ultra-shallow junction and the substrate, a plurality of impurity ions in the drain-substrate junction and a plurality of impurity ions in the lightly-doped ultra-shallow junction are opposite-conductivity type ions. The drain-substrate junction can smooth out the steep surface of the lightly-doped ultra-shallow junction to minimize the maximum electric field and reduce the ion flow close to the channel, and effectively reduce the inter-band tunneling hot electron effect.

A method of manufacturing a multi-finger transistor structure is provided in the present invention, including forming shallow trench isolations in a substrate to define multiple active areas, forming a gate structure on the substrate, wherein the gate structure includes multiple gate parts and multiple connecting parts, and each gate part traverses over one of the active area, and each connecting part alternatively connect one end and the other end of two adjacent gate parts, so as to form meander gate structure.

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.

NAND string configurations and semiconductor memory arrays that include such NAND string configurations are provided. Methods of making semiconductor memory cells used in NAND string configurations are also described.