A lateral semiconductor device and/or design including a space-charge generating layer and an electrode or a set of electrodes located on an opposite side of a device channel as contacts to the device channel is provided. The space-charge generating layer is configured to form a space-charge region to at least partially deplete the device channel in response to an operating voltage being applied to the contacts to the device channel.

A semiconductor structure of a split gate flash memory cell is provided. The semiconductor structure includes a semiconductor substrate including a first source/drain region and a second source/drain region. The first and second source/drain regions form a channel region therebetween. The semiconductor structure further includes a select gate and a memory gate spaced between the first and second source/drain regions over the channel region. The select gate extends over the channel region and terminates at a line end having a top surface asymmetric about an axis that extends along a length of the select gate and that bisects a width of the select gate. Even more, the semiconductor structure includes a charge trapping dielectric arranged between neighboring sidewalls of the memory gate and the select gate, and arranged under the memory gate. A method of manufacturing the semiconductor structure is also provided.

An ESD protection semiconductor device includes a substrate, a gate set formed on the substrate, a source region and a drain region formed in the substrate respectively at two sides of the gate set, and at least a first doped region formed in the drain region. The source region and the drain region include a first conductivity type, and the first doped region includes a second conductivity type. The first conductivity type and the second conductivity type are complementary to each other. The first doped region is electrically connected to a ground potential.

A semiconductor device and method of fabricating the semiconductor device are disclosed. The method includes forming a plurality of gate electrodes at a predetermined interval on a surface of a semiconductor substrate, forming spacers on sidewalls of the gate electrodes, depositing an interconnection layer conformally on the surface of the semiconductor substrate over the gate electrodes and the spacers, selectively etching the interconnection layer, wherein at least a portion of the interconnection layer that is formed on the surface of the semiconductor substrate and sidewalls of the spacers and located between adjacent gate electrodes remains after the selective etch, and forming an electrical contact on the etched interconnection layer located between the adjacent gate electrodes.

A semiconductor device, including: a plurality of non-volatile memory cells including a first memory cell and a second memory cell, where the plurality of non-volatile memory cells includes source diffusion lines and drain diffusion lines, at least one of the source diffusion lines and drain diffusion lines are shared by the first memory cell and the second memory cell, where the first memory cell includes a thin tunneling oxide of less than 1 nm thickness, and where the second memory cell includes a thick tunneling oxide of greater than 2 nm thickness.

The present invention relates to a junction field effect transistor. The junction field effect transistor comprises a substrate (10), a buried layer in the substrate, a first well region (32) and a second well region (34) that are on the buried layer, a source lead-out region (50), a drain lead-out region (60), and a first gate lead-out region (42) that are in the first well region (32), and a second gate lead-out region (44) in the second well region (34). A Schottky junction interface (70) is disposed on the surface of the first well region (32). The Schottky junction interface (70) is located between the first gate lead-out region (42) and the drain lead-out region (60), and is isolated from the first gate lead-out region (42) and the drain lead-out region (60) by means of isolation structures. The present invention also relates to a manufacturing method for a junction field effect transistor.

The present disclosure relates to a flash memory device, and associated methods. In some embodiments, the flash memory device has a gate stack with a control gate separated from a floating gate by a control gate dielectric. An erase gate disposed on a first side of the gate stack. A word line is disposed on a second side of the gate stack that is opposite the first side. The word line has a height that monotonically increases from an outer side opposite to the gate stack to an inner side closer to the gate stack. The shape of the word line optimizes the contact resistance of the word line and allows for an overlying cap spacer formed on the word line to be well defined, which can provide more reliable read/write operations and/or better performance.

A semiconductor structure including vertical transistors is provided in which a sigma shaped source/drain extension region is formed between a top faceted surface of a first region of an epitaxial semiconductor channel material and a bottom faceted surface of a second region of the epitaxial semiconductor channel material. The sigma shaped source/drain extension region is formed after formation of a functional gate structure on each side of an epitaxial semiconductor channel material by first removing a sacrificial bottom spacer layer of a bottom spacer material stack, performing a sigma etch on an exposed lower portion of the epitaxial semiconductor channel material to provide the first region of epitaxial semiconductor channel material and the second region of the epitaxial semiconductor channel material, and then epitaxially growing the sigma shaped source/drain extension region from the faceted surfaces of the first and second regions of epitaxial semiconductor channel material.

A semiconductor device includes a split-gate lateral extended drain MOS transistor, which includes a first gate and a second gate laterally adjacent to the first gate. The first gate is laterally separated from the second gate by a gap of 10 nanometers to 250 nanometers. The first gate extends at least partially over the body, and the second gate extends at least partially over a drain drift region. The drain drift region abuts the body at a top surface of the substrate. A boundary between the drain drift region and the body at the top surface of the substrate is located under at least one of the first gate, the second gate and the gap between the first gate and the second gate. The second gate may be coupled to a gate bias voltage node or a gate signal node.

A semiconductor device includes an n-type vertical field-effect transistor (FET) that includes: a first source/drain feature disposed in a substrate; a first vertical bar structure that includes a first sidewall and a second sidewall disposed over the substrate; a gate disposed along the first sidewall of the first vertical bar structure; a second vertical bar structure electrically coupled to the first vertical bar structure; and a second source/drain feature disposed over the first vertical bar structure; and a p-type FET that includes; a third source/drain feature disposed in the substrate; a third vertical bar structure that includes a third sidewall and a fourth sidewall disposed over the substrate; the gate disposed along the third sidewall of the third vertical bar structure; a fourth vertical bar structure electrically coupled to the third vertical bar structure; and a fourth source/drain feature disposed over the third vertical bar structure.