Device structures for a high-voltage semiconductor device and methods of forming such device structures. The structure comprises a semiconductor substrate and a layer stack including a first dielectric layer and a second dielectric layer. The first dielectric layer is positioned between the second dielectric layer and the semiconductor substrate. The structure further comprises a field-effect transistor including a first source/drain region in the semiconductor substrate, a second source/drain region in the semiconductor substrate, and a metal gate on the layer stack laterally between the first source/drain region and the second source/drain region. The second dielectric layer is positioned between the metal gate and the first dielectric layer. A contact extends through the layer stack to the first source/drain region.

A semiconductor device includes a substrate having a fin element extending therefrom. In some embodiments, a gate structure is formed over the fin element, where the gate structure includes a dielectric layer on the fin element, a metal capping layer disposed over the dielectric layer, and a metal electrode formed over the metal capping layer. In some cases, first sidewall spacers are formed on opposing sidewalls of the metal capping layer and the metal electrode. In various embodiments, the dielectric layer extends laterally underneath the first sidewall spacers to form a dielectric footing region.

A device includes a substrate. A first channel region of a first transistor overlies the substrate and a source/drain region is in contact with the first channel region. The source/drain region is adjacent to the first channel region along a first direction, and the source/drain region has a first surface opposite the substrate and side surfaces extending from the first surface. A dielectric fin structure is adjacent to the source/drain region along a second direction that is transverse to the first direction, and the dielectric fin structure has an upper surface, a lower surface, and an intermediate surface that is disposed between the upper and lower surfaces. A silicide layer is disposed on the first surface and the side surfaces of the source/drain region and on the intermediate surface of the dielectric fin structure.

A device includes a substrate. A first channel region of a first transistor overlies the substrate and a source/drain region is in contact with the first channel region. The source/drain region is adjacent to the first channel region along a first direction, and the source/drain region has a first surface opposite the substrate and side surfaces extending from the first surface. A dielectric fin structure is adjacent to the source/drain region along a second direction that is transverse to the first direction, and the dielectric fin structure has an upper surface, a lower surface, and an intermediate surface that is disposed between the upper and lower surfaces. A silicide layer is disposed on the first surface and the side surfaces of the source/drain region and on the intermediate surface of the dielectric fin structure.

A method includes forming a dummy gate stack, etching the dummy gate stack to form an opening, depositing a first dielectric layer extending into the opening, and depositing a second dielectric layer on the first dielectric layer and extending into the opening. A planarization process is then performed to form a gate isolation region including the first dielectric layer and the second dielectric layer. The dummy gate stack is then removed to form trenches on opposing sides of the gate isolation region. The method further includes performing a first etching process to remove sidewall portions of the first dielectric layer, performing a second etching process to thin the second dielectric layer, and forming replacement gates in the trenches.

A semiconductor device is disclosed that includes a plurality of fins on a substrate. A long channel gate is disposed over a first portion of the plurality of fins. A gate contact is provided having an extended portion that extends into an active area from a gate contact base outside the active area.

An integrated circuit includes a first chip bonded to a second chip. The first chip includes gate all around transistors on a substrate. The first chip includes backside conductive vias extending through the substrate to the gate all around transistors. The second chip includes electronic circuitry electrically connected to the transistors by the backside conductive vias.

A nanoscale thin film structure and implementing method thereof, and, more specifically, a nanoscale thin film structure of which target structure is designed with quantized thickness, and a method to implement the nanoscale thin film structure by which the performance of the manufactured nanodevice can be implemented the same as the designed performance, thereby applicable to high sensitivity high performance electronic/optical sensor devices.

A microelectronic structure includes a first row of stack nano devices that includes a plurality of a first stacked nano FET devices and a second row of stack nano devices that includes a plurality of a second stacked nano FET devices. Each of the plurality of first nano stacked FET devices and each of the plurality of second stacked FET devices includes an upper stack transistor and a lower stack transistor. A gate cut located between the first row of stacked nano devices and the second row stacked nano devices. An interconnect located within gate cut. The interconnect is connected to a source/drain of one of the lower stacked transistors and the interconnect includes a non-uniform backside surface.

A semiconductor device fabrication method is provided and includes forming first and second stacks each including a dual layer top dielectric cap (TDC), sequentially surrounding each layer and a portion of the dual layer TDC of the first stack with high-k dielectric, a first work function metal (WFM) and a second WFM, sequentially surrounding each layer and a portion of the dual layer TDC of the second stack with the high-k dielectric and the second WFM, forming gate metal around the first and second stacks and recessing the gate metal and the second WFM to a depth defined above a height of an uppermost first WFM horizontal portion.