According to example embodiments, an integrated circuit includes a continuous active region extending in a first direction, a tie gate electrode extending in a second direction crossing the first direction on the continuous active region, a source/drain region provided adjacent the tie gate electrode, a tie gate contact extending in a third direction perpendicular to the first direction and the second direction on the continuous active region and connected to the tie gate electrode, a source/drain contact extending in the third direction and connected to the source/drain region, and a wiring pattern connected to each of the tie gate contact and the source/drain contact and extending in a horizontal direction. A positive supply power is applied to the wiring pattern.

A silicon on insulator substrate includes a semiconductor bulk handle wafer, an insulating layer on said semiconductor bulk handle wafer and a semiconductor film on said insulating layer. An opening extends completely through the semiconductor film and insulating layer to expose a surface of the semiconductor bulk handle wafer. Epitaxial material fills the opening and extends on said semiconductor film, with the epitaxial material and semiconductor film forming a thick semiconductor film. A trench isolation surrounds a region of the thick semiconductor film to define an electrical contact made to the semiconductor bulk handle wafer through the opening.

A silicon on insulator substrate includes a semiconductor bulk handle wafer, an insulating layer on said semiconductor bulk handle wafer and a semiconductor film on said insulating layer. An opening extends completely through the semiconductor film and insulating layer to expose a surface of the semiconductor bulk handle wafer. Epitaxial material fills the opening and extends on said semiconductor film, with the epitaxial material and semiconductor film forming a thick semiconductor film. A trench isolation surrounds a region of the thick semiconductor film to define an electrical contact made to the semiconductor bulk handle wafer through the opening.

Single gate and dual gate FinFET devices suitable for use in an SRAM memory array have respective fins, source regions, and drain regions that are formed from portions of a single, contiguous layer on the semiconductor substrate, so that STI is unnecessary. Pairs of FinFETs can be configured as dependent-gate devices wherein adjacent channels are controlled by a common gate, or as independent-gate devices wherein one channel is controlled by two gates. Metal interconnects coupling a plurality of the FinFET devices are made of a same material as the gate electrodes. Such structural and material commonalities help to reduce costs of manufacturing high-density memory arrays.

A semiconductor device includes a Fin FET device. The Fin FET device includes a first fin structure extending in a first direction and protruding from an isolation insulating layer, a first gate stack including a first gate electrode layer and a first gate dielectric layer, covering a portion of the first fin structure and extending in a second direction perpendicular to the first direction, and a first source and a first drain, each including a first stressor layer disposed over the first fin structure. The first fin structure and the isolation insulating layer are disposed over a substrate. A height Ha of an interface between the first fin structure and the first stressor layer measured from the substrate is greater than a height Hb of a lowest height of the isolation insulating layer measured from the substrate.

Various embodiments of the present application are directed towards a semiconductor-on-insulator (SOI) substrate. The SOI substrate includes a handle substrate; a device layer overlying the handle substrate; and an insulator layer separating the handle substrate from the device layer. The insulator layer meets the device layer at a first interface and meets the handle substrate at a second interface. The insulator layer comprises a getter material having a getter concentration profile. The handle substrate contains getter material and has a handle getter concentration profile. The handle getter concentration profile has a peak at the second interface and a gradual decline beneath the second interface until reaching a handle getter concentration.

Various embodiments of the present application are directed towards a semiconductor-on-insulator (SOI) substrate. The SOI substrate includes a handle substrate; a device layer overlying the handle substrate; and an insulator layer separating the handle substrate from the device layer. The insulator layer meets the device layer at a first interface and meets the handle substrate at a second interface. The insulator layer comprises a getter material having a getter concentration profile. The handle substrate contains getter material and has a handle getter concentration profile. The handle getter concentration profile has a peak at the second interface and a gradual decline beneath the second interface until reaching a handle getter concentration.

A monolithic multi-FET transistor comprises an epitaxial layer disposed on a dielectric layer. The epitaxial layer comprises a crystalline semiconductor material and a multi-FET area. An isolation structure surrounds the multi-FET area and divides the multi-FET area into separate FET portions. A gate disposed on a gate dielectric extends over each FET portion. A source and a drain are each disposed on opposite sides of the gate on the epitaxial layer within each FET portion. Each gate, source, and drain comprise a separate electrical conductor and the gate, source, drain, and epitaxial layer within each FET portion form a field-effect transistor. Gate, source, and drain contacts electrically connect the gates, sources, and drains of the separate FET portions, respectively. At least the sources or drains of two neighboring FET portions are disposed in common over at least a portion of the isolation structure dividing the two neighboring FET portions.

A monolithic multi-FET transistor comprises an epitaxial layer disposed on a dielectric layer. The epitaxial layer comprises a crystalline semiconductor material and a multi-FET area. An isolation structure surrounds the multi-FET area and divides the multi-FET area into separate FET portions. A gate disposed on a gate dielectric extends over each FET portion. A source and a drain are each disposed on opposite sides of the gate on the epitaxial layer within each FET portion. Each gate, source, and drain comprise a separate electrical conductor and the gate, source, drain, and epitaxial layer within each FET portion form a field-effect transistor. Gate, source, and drain contacts electrically connect the gates, sources, and drains of the separate FET portions, respectively. At least the sources or drains of two neighboring FET portions are disposed in common over at least a portion of the isolation structure dividing the two neighboring FET portions.

A semiconductor structure and a method for forming a semiconductor structure are provided. The method includes receiving a semiconductor substrate having a first region and a second region; forming a dielectric layer over the semiconductor substrate; removing portions of the dielectric layer to form a dielectric structure in the first region, wherein the dielectric structure includes a base structure and a plurality of first isolation structures over the base structure; forming a semiconductor layer covering the first region and the second region; removing a portion of the semiconductor layer to expose a top surface of the plurality of first isolation structures; and forming a plurality of second isolation structures in the second region.