The present disclosure describes semiconductor devices and methods for forming the same. A semiconductor device includes nanostructures over a substrate and a source/drain region in contact with the nanostructures. The source/drain region is doped with a first-type dopant. The semiconductor device also includes a counter-doped structure in contact with the substrate and the source/drain region. The counter-doped structure is doped with a second-type dopant opposite to the first-type dopant.

An integrated circuit includes a device region and an overlay mark region. The device region includes a plurality of stacked channels of a transistor, a source/drain region of the transistor, a source/drain contact of a first material on the source/drain region, and a conductive via of a second material in contact with the source/drain contact. The overlay mark region includes a first diffraction grating of first metal structures of the first material and a second first diffraction grating of second metal structures above of the second material above and offset from the first metal structures.

A method includes forming first nanostructures over a first region of a substrate; forming second nanostructures over a second region of the substrate; forming a first gate structure around the first nanostructures; replacing the second nanostructures with isolation regions; and forming a through via extending through isolation regions and into the substrate.

A semiconductor structure including an array of transistors, a backside power rail, wherein the backside power rail directly contacts a bottommost surface of a shallow trench isolation region, and a metal-insulator-metal (MIM) capacitor embedded in a backside power delivery network beneath the array of transistors, wherein the MIM capacitor directly contacts a bottommost surface of the backside power rail.

Integrated circuit (IC) chips and seal ring structures are provided. An IC chip according to the present disclosure includes a circuit region and a seal ring region surrounding the circuit region. The seal ring region includes a first active region extending lengthwise in a first direction and a first gate structure disposed on the first active region. The first gate structure extends lengthwise in a second direction that is tilted from the first direction. The first direction and the second direction form a tilted angle therebetween.

A method includes performing an atomic layer deposition (ALD) process to form a dielectric layer on a wafer. The ALD process comprises an ALD cycle includes pulsing calypso ((SiCl.sub.3).sub.2CH.sub.2), purging the calypso, pulsing ammonia, and purging the ammonia. The method further includes performing a wet anneal process on the dielectric layer, and performing a dry anneal process on the dielectric layer.

Implementations described herein provide a method of forming a semiconductor device. The method includes forming a nanostructure having a first set of layers of a first material and a second set of layers, alternating with the first set of layers, having a second material. The method further includes depositing a hard mask on a top layer of the first set of layers, the hard mask including a first hard mask layer on the top layer of the first set of layers and a second hard mask layer on the first hard mask layer. The method also includes depositing elements of a cladding structure on sidewalls of the nanostructure and the hard mask. The method further includes removing a top portion of the cladding structure. The method further includes removing the second hard mask layer after removing the top portion of the cladding structure.

A device includes a substrate, a first stack of semiconductor nanostructures vertically overlying the substrate, and a gate structure surrounding the semiconductor nanostructures and abutting an upper side and first and second lateral sides of the first stack. A first epitaxial region laterally abuts a third lateral side of the first stack, and a second epitaxial region laterally abuts a fourth lateral side of the first stack. A first inactive fin laterally abuts the first epitaxial region, and a second inactive fin laterally abuts the second epitaxial region and is physically separated from the first inactive fin by the gate structure.

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.