A semiconductor device includes a deep well region located on a substrate, a drift region located in the deep well region, a first gate electrode that overlaps with the first body region and the drift region, a second gate electrode that overlaps with the second body region and the drift region, a first source region and a second source region located in the first and second body regions, respectively, a drain region located in the drift region and disposed between the first gate electrode and the second gate electrode, a silicide layer located on the substrate, a first non-silicide layer located between the drain region and the first gate electrode, wherein the first non-silicide layer extends over a top surface of the first gate electrode, and a first field plate contact plug in contact with the first non-silicide layer.

A semiconductor device includes a source/drain diffusion area, a first doped region and a gate. The source/drain diffusion area, defined between a first isolation structure and a second isolation structure, includes a source region, a drain region and a device channel. The first doped region, disposed along a first junction between the device channel and the first isolation structure, is separated from at least one of the source region and the drain region. The first doped region has a dopant concentration higher than that of the device channel. The gate is disposed over the source/drain diffusion area. The first doped region is located within a projected area of the gate onto the source/drain diffusion area, the first isolation structure and the second isolation structure. A length of the first doped region is shorter than a length of the gate in a direction from the source region to the drain region.

A main semiconductor device element has first and second p.sup.+-type high-concentration regions that mitigate electric field applied to bottoms of trenches. The first p.sup.+-type high-concentration regions are provided separate from p-type base regions, face the bottoms of the trenches in a depth direction, and extend in a linear shape in a first direction that is a same direction in which the trenches extend. Between adjacent trenches of the trenches, the second p.sup.+-type high-concentration regions are provided scattered in the first direction, separate from the first p.sup.+-type high-concentration regions and the trenches and in contact with the p-type base regions. Between the second p.sup.+-type high-concentration regions adjacent to one another in the first direction, n-type current spreading regions or n.sup.+-type high-concentration regions having an impurity concentration higher than that of the n-type current spreading regions are provided in contact with the second p.sup.+-type high-concentration regions.

A semiconductor device comprises: a substrate; a well region provided in the substrate, having a second conductivity type; source regions having a first conductivity type; body tile regions having the second conductivity type, the source regions and the body tie regions being alternately arranged in a conductive channel width direction so as to form a first region extending along the conductive channel width direction, and a boundary where the edges of the source regions and the edges of the body tie regions are alternately arranged being formed on two sides of the first region; and a conductive auxiliary region having the first conductivity type, provided on at least one side of the first region, and directly contacting the boundary, a contact part comprising the edge of at least one source region on the boundary and the edge of at least one body tie region on the boundary.

Methods of forming a self-aligned gate (SAG) and self-aligned source (SAD) device for high E.sub.crit semiconductors are presented. A dielectric layer is deposited on a high E.sub.crit substrate. The dielectric layer is etched to form a drift region. A refractory material is deposited on the substrate and dielectric layer. The refractory material is etched to form a gate length. Implant ionization is applied to form high-conductivity and high-critical field strength source with SAG and SAD features. The device is annealed to activate the contact regions. Alternately, a refractory material may be deposited on a high E.sub.crit substrate. The refractory material is etched to form a channel region. Implant ionization is applied to form high-conductivity and high E.sub.crit source and drain contact regions with SAG and SAD features. The refractory material is selectively removed to form the gate length and drift regions. The device is annealed to activate the contact regions.

To provide a technique capable of improving performance and reliability of a semiconductor device. An n.sup.−-type epitaxial layer (12) is formed on an n-type semiconductor substrate (11), and a p.sup.+-type body region (14), n.sup.+-type current spreading regions (16, 17), and a trench. TR are formed in the n.sup.−-type epitaxial layer (12). A bottom surface B1 of the trench TR is located in the p.sup.+-type body region (14), a side surface S1 of the trench TR is in contact with the n.sup.+-type current spreading region (17), and a side surface S2 of the trench TR is in contact with the n.sup.+-type current spreading region (16). Here, a ratio of silicon is higher than a ratio of carbon in an upper surface T1 of the n.sup.−-type epitaxial layer (12), and the bottom surface B1, the side surface S1, and the side surface 32 of the trench. Furthermore, an angle θ1 at which the upper surface T1 of the n.sup.−-type epitaxial layer (12) is inclined with respect to the side surface S1 is smaller than an angle θ2 at which the upper surface T1 of the n.sup.−-type epitaxial layer (12) is inclined with respect to the side surface S2.

Structures for an extended-drain metal-oxide-semiconductor device and methods of forming a structure for an extended-drain metal-oxide-semiconductor device. The structure includes a semiconductor substrate containing a first semiconductor material, a source region and a drain region in the semiconductor substrate, a gate electrode positioned in a lateral direction between the source region and the drain region, and a semiconductor layer positioned on the semiconductor substrate. The semiconductor layer contains a second semiconductor material that differs in composition from the first semiconductor material. The gate electrode includes a first section positioned in a vertical direction over the semiconductor layer and a second section positioned in the vertical direction over the semiconductor substrate.

A semiconductor device includes a deep well region located on a substrate, a drift region located in the deep well region, a first gate electrode that overlaps with the first body region and the drift region, a second gate electrode that overlaps with the second body region and the drift region, a first source region and a second source region located in the first and second body regions, respectively, a drain region located in the drift region and disposed between the first gate electrode and the second gate electrode, a silicide layer located on the substrate, a first non-silicide layer located between the drain region and the first gate electrode, wherein the first non-silicide layer extends over a top surface of the first gate electrode, and a first field plate contact plug in contact with the first non-silicide layer.

A switch is provided having a switch transistor as well as a monitoring component to monitor a control signal applied to the switch transistor. With the monitoring component, in some implementation a monitoring of the control signal independent from a load path may be possible.

N-channel power semiconductor devices in which an insulated field plate is coupled to the drift region, and immobile electrostatic charge is also present at the interface between the drift region and the insulation around the field plate. The electrostatic charge permits OFF-state voltage drop to occur near the source region, in addition to the voltage drop which occurs near the drain region (due to the presence of the field plate).