Abstract: A method is provided. The method includes the following steps: identifying a first intellectual property (IP) block and a second IP block in an integrated circuit; identifying a small border region between the first IP block and the second IP block, wherein the small border region has a width in a first horizontal direction, and the width is between a small border region dimension lower limit and a small border region dimension upper limit; and inserting at least one small dummy gate feature pattern in the small border region.

Abstract: A semiconductor device includes a transistor, which includes a gate structure, a first source/drain structure, and a second source/drain structure. The gate structure is laterally disposed between the first source/drain structure and the second source/drain structure. The first source/drain structure and the second source/drain structure are formed in a first silicon layer disposed over a second silicon layer. The first silicon layer having at least a portion in direct contact with the second silicon layer. The second silicon layer includes a plurality of buried oxide layers.

Abstract: A semiconductor device includes a first silicon layer. The semiconductor device includes a plurality of first buried oxide layers embedded in the first silicon layer. The semiconductor device includes a second silicon layer disposed over the plurality of first buried oxide layers. Vertical distances between the plurality of first buried oxide layers and the second silicon layer, respectively, are different.

Abstract: In accordance with some aspects of the disclosure, a semiconductor structure is provided. The semiconductor structure includes: an active region; and a gate stack disposed on the active region. The gate stack includes: at least one gate dielectric layer disposed on the active region; and a metal gate structure disposed on the at least one gate dielectric layer. The metal gate structure includes: a metal gate layer comprising a first material; and at least one dummy structure disposed in the metal gate layer, the at least one dummy structure extending vertically through an entire thickness of the metal gate structure and comprising a second material. The second material is different from the first material.

Abstract: An integrated circuit (IC) with active and dummy device cell arrays and a method of fabricating the same are discloses. The IC includes a substrate, an active device cell, and a dummy device cell. The active device cell includes an array of source/drain (S/D) regions of a first conductivity type disposed on or within the substrate and an array of gate structures with a first gate fill material disposed on the substrate. The dummy device cell includes a first array of S/D regions of the first conductivity type disposed on or within the substrate, a second array of S/D regions of a second conductivity type disposed on or within the substrate, and an array of dual gate structures disposed on the substrate. Each of the dual gate structures includes the first gate fill material and a second gate fill material that is different from the first gate fill material.

Abstract: A method for forming a semiconductor device includes providing a semiconductor substrate, implanting n-type impurities into a device region in the semiconductor substrate to form an implanted region and an un-implanted region. The method also includes forming an epitaxial layer on the semiconductor substrate and forming a trench surrounding the device region in direct contact with the implanted region. The method further includes performing a selective lateral etch through the trench to remove the implanted region to form a cavity under the epitaxial layer. The un-implanted region is retained to form a pillar under the epitaxial layer. Next, an insulating material is disposed in the cavity and the trench. The method forms a single crystalline region that is separated from the semiconductor substrate by the insulating material except at the pillar.

Abstract: A semiconductor structure including a substrate, a first well region, a second well region, an isolation, a gate structure, and a dielectric layer is provided. The first well region is disposed in the substrate, wherein a dopant of the first well region includes arsenic. The second well region is disposed in the substrate under the first well region, wherein the second well region has a conductivity type different from that of the first doping region. The isolation is disposed in the substrate and surrounds the first well region, wherein a depth of the isolation is substantially greater than or equal to a depth of the first well region from a first surface of the substrate. The gate structure are disposed sequentially over the substrate and overlaps the first well region. A method of forming the semiconductor structure is also provided.

Abstract: An integrated circuit (IC) with active and dummy device cell arrays and a method of fabricating the same are discloses. The IC includes a substrate, an active device cell, and a dummy device cell. The active device cell includes an array of source/drain (S/D) regions of a first conductivity type disposed on or within the substrate and an array of gate structures with a first gate fill material disposed on the substrate. The dummy device cell includes a first array of S/D regions of the first conductivity type disposed on or within the substrate, a second array of S/D regions of a second conductivity type disposed on or within the substrate, and an array of dual gate structures disposed on the substrate. Each of the dual gate structures includes the first gate fill material and a second gate fill material that is different from the first gate fill material.

Abstract: A semiconductor device includes a first silicon layer. The semiconductor device includes a plurality of first buried oxide layers embedded in the first silicon layer. The semiconductor device includes a second silicon layer disposed over the plurality of first buried oxide layers. Vertical distances between the plurality of first buried oxide layers and the second silicon layer, respectively, are different.