Present disclosure provides a transistor structure, including a substrate, a first gate over the substrate, a second gate over the substrate and laterally in contact with the first gate, a first conductive region of a first conductivity type in the substrate, self-aligning to a side of the first gate, and a second conductive region of the first conductivity type in the substrate, self-aligning to a side of the second gate. A method for manufacturing the transistor structure is also disclosed.

A method for producing an FET transistor includes producing a transistor channel, comprising at least one semiconductor nanowire arranged on a substrate and comprising first and second opposite side faces; producing at least two dummy gates, each arranged against one of the first and second side faces of the channel; etching a first of the two dummy gates, forming a first gate location against the first side face of the channel; producing a first gate in the first gate location and against the first side face of the channel; etching a second of the two dummy gates, forming a second gate location against the second side face of the channel; and producing a second gate in the second gate location and against the second side face of the channel.

A method for semiconductor devices on a substrate includes using gate structures which serve as active gate structures in a MOSFET region, as dummy gate structures in a JFET region of the device. The dummy gate electrodes are used as masks and determine the spacing between gate regions and source/drain regions, the width of the gate regions, and the spacing between adjacent gate regions according to some embodiments, thereby forming an accurately dimensioned transistor channel.

An includes an epitaxial sub-fin structure disposed on a substrate, wherein a first portion of the sub-fin structure is disposed within a portion of the substrate, and a second portion of the sub-fin structure is disposed adjacent a dielectric material. A fin device structure is disposed on the sub-fin structure, wherein the fin device structure comprises the epitaxial material. A liner is disposed between the second portion of the sub-fin structure and the dielectric material. Other embodiments are described herein.

At least one method, apparatus and system disclosed involves providing semiconductor device having transistors comprising back gates and front gates. The semiconductor device comprises a signal processing unit for processing an input signal to provide an output signal. The signal processing unit includes a first transistor and a second transistor. The first transistor includes a first back gate electrically coupled to a first front gate. The signal processing unit also includes a second transistor operatively coupled to the first transistor. The second transistor includes a second back gate electrically coupled to a second front gate. The semiconductor device also includes a gain circuit for providing a gain upon the output signal. The semiconductor device also includes a bias circuit to provide a first bias signal to the first back gate and a second bias signal to the second back gate.

A method manufactures exchange gates from a starting structure including a substrate and, disposed on the substrate, a plurality of gate stacks, each gate stack including, a layer of a conductive or semiconductor material and a layer of a hard mask.

A semiconductor substrate having a gate dielectric layer and a conductive layer is provided. The conductive layer is patterned into a main gate portion. A drain region and a source region are formed on two sides of the main gate portion, respectively. By thinning down the gate dielectric layer after patterning the conductive layer into the main gate portion, a first portion of the gate dielectric layer on the drain region, a second portion of the gate dielectric layer between a channel region and the main gate portion, and a third portion of the gate dielectric layer on the source region are formed. A first extension gate portion and a second extension gate portion are formed on two opposite sidewalls of the main gate portion, respectively. The main gate portion, the first extension gate portion and the second extension gate portion constitute a gate electrode of the MOS transistor.

A method of forming a comb-shaped transistor device is provided. The method includes forming a stack of alternating sacrificial spacer segments and channel segments on a substrate. The method further includes forming channel sidewalls on opposite sides of the stack of alternating sacrificial spacer segments and channel segments, and dividing the stack of alternating sacrificial spacer segments and channel segments into alternating sacrificial spacer slabs and channel slabs, wherein the channel slabs and channel sidewalls form a pair of comb-like structures. The method further includes trimming the sacrificial spacer slabs and channel slabs to form a nanosheet column of sacrificial plates and channel plates, and forming source/drains on opposite sides of the sacrificial plates and channel plates.

Existing semiconductor transistor processes may be leveraged to form lateral extensions adjacent to a conventional gate structure. The dielectric thickness under these lateral gate extensions can be varied to optimize device channel resistance and enable resistance to breakdown at high operating voltages. These extensions may be patterned with dimensions that are not limited by lithographic resolution and overlay capabilities and are compatible with conventional processing for ease of integration with other devices. The lateral extensions and dielectric spacers may be used to form self-aligned source, drain, and channel regions. A thin dielectric layer may be formed under an extension gate to reduce channel resistance. A thick dielectric layer may be formed under an extension gate to improve operation voltage range. The present invention provides an innovative structure with lateral gate extensions which may be referred to as EGMOS (extended gate metal oxide semiconductor).

A method of manufacturing a semiconductor device includes forming a fin structure in which first semiconductor layers and second semiconductor layers are alternatively stacked; forming a sacrificial gate structure over the fin structure; etching a source/drain (S/D) region of the fin structure, which is not covered by the sacrificial gate structure, thereby forming an S/D space; laterally etching the first semiconductor layers through the S/D space, thereby forming recesses; forming a first insulating layer, in the recesses, on the etched first semiconductor layers; after the first insulating layer is formed, forming a second insulating layer, in the recesses, on the first insulating layer, wherein a dielectric constant of the second insulating layer is less than that of the first insulating layer; and forming an S/D epitaxial layer in the S/D space, wherein the second insulating layer is in contact with the S/D epitaxial layer.