A laterally diffused metal oxide semiconductor (LDMOS) device that may include an oxide region that comprises a bottom surface; a drain that is positioned between a left drift region and a right drift region and below the bottom surface; wherein the oxide region further comprises a first sloped surface and a second sloped surface; wherein a first angle between the first sloped surface and the bottom surface does not exceed twenty degrees; and wherein a second angle between the second sloped surface and the bottom surface of the oxide region does not exceed twenty degrees.

Semiconductor devices and methods for manufacturing the same are provided. In one embodiment, the method may include: forming a first shielding layer on a substrate, and forming one of source and drain regions with the first shielding layer as a mask; forming a second shielding layer on the substrate, and forming the other of the source and drain regions with the second shielding layer as a mask; removing a portion of the second shielding layer which is next to the other of the source and drain regions; forming a gate dielectric layer, and forming a gate conductor as a spacer on a sidewall of a remaining portion of the second shielding layer; and forming a stressed interlayer dielectric layer on the substrate.

An integrated circuit and method having an LDMOS transistor with multiple current channels. A first current channel is above a buried p-type diffusion and a second one current channel is below the buried p-type diffusion.

A double-RESURF LDMOS transistor has a gate dielectric structure including a shallow field “bump” oxide region and an optional raised dielectric structure that provides a raised support for the LDMOS transistor's polysilicon gate electrode. Fabrication of the shallow field oxide region is performed through a hard “bump” mask and controlled such that the bump oxide extends a minimal depth into the LDMOS transistor's drift (channel) region. The hard “bump” mask is also utilized to produce an N-type drift (N-drift) implant region and a P-type surface effect (P-surf) implant region, whereby these implants are “self-aligned” to the gate dielectric structure. The N-drift implant is maintained at Vdd by connection to the LDMOS transistor's drain diffusion. An additional Boron implant is utilized to form a P-type buried layer that connects the P-surf implant to the P-body region of the LDMOS transistor, whereby the P-surf implant is maintained at 0V.

A semiconductor device includes a substrate including a first region and a second region, a first transistor and a second transistor formed in the first region and second region, respectively, wherein the first transistor includes a thick gate insulating layer and a thin buffer insulating layer formed in the substrate, a first gate electrode formed on the thick gate insulating layer, a first spacer formed on the thin buffer insulating layer, and a source region and a drain region formed in the substrate.

Integrated circuits including LDMOS transistor structures and methods for fabricating LDMOS transistor structures are provided. An exemplary method for fabricating an LDMOS transistor structure includes providing a semiconductor-on-insulator (SOI) substrate including a semiconductor layer overlying an insulator layer overlying a bulk layer. The method includes forming a gate structure overlying the substrate. A channel region is formed in the semiconductor layer under the gate structure. The method includes forming a source region overlying the substrate. Further, the method includes forming a drain region overlying the substrate. A drift region is located between the drain region and the gate structure. Also, the method includes forming contacts to the gate structure, the source region, and the drain region.

A gate electrode structure and a high voltage semiconductor device having the same are disclosed. The gate electrode structure includes a gate insulation layer pattern disposed on a substrate, a gate electrode disposed on the gate insulating layer pattern and having at least one opening at a first side portion thereof, and at least one insulating pattern disposed in the at least one opening. The high voltage semiconductor device includes a drift region disposed in the substrate adjacent to the first side portion of the gate electrode, a drain region electrically connected with the drift region, and a source region disposed in the substrate adjacent to a second side portion of the gate electrode.

A method of forming a HVMOS transistor device is provided. A substrate is provided. A first insulation structure and a trench are formed in the substrate. A base region having a second conductivity type is formed, wherein the base region completely encompasses the trench. Next, a gate dielectric layer and a gate structure are formed in the trench and covering a portion of the first insulation structure. Then, a drain region and a source region are formed in the substrate at two respective sides of the gate structure, and the drain region and the source region comprise a first conductivity type complementary to the second conductivity type. A channel is defined between the source region and the drain region along a first direction.

Described examples include an integrated circuit having a semiconductor substrate having an epitaxial layer located thereon, the epitaxial layer having a surface. The integrated circuit also has a buried layer formed in the semiconductor substrate, the epitaxial layer located between the buried layer and the surface. The integrated circuit also has a Schottky contact and an ohmic contact formed on the surface. The integrated circuit also has a Pdrift region in the epitaxial layer located between the ohmic contact and the Schottky contact.

A method for eliminating divot formation includes forming an isolation layer; forming a conduction layer which has an upper inclined boundary with the isolation layer such that the conduction layer has a portion located above a portion of the isolation layer at the upper inclined boundary; etching back the isolation layer; and etching back the conduction layer after etching back the isolation layer such that a top surface of the etched conduction layer is located at a level lower than a top surface of the etched isolation layer.