An isolator includes a substrate; a first insulating film on the substrate; a second insulating film on the first insulating film, a third insulating film on the second insulating film, a first interconnect in the second insulating film, and first and second coils. The first interconnect has a thickness equal to a film thickness of the second insulating film. The first coil extends in the first and second insulating films. The first coil has a length in the extending direction greater than the thickness of the first interconnect. The third insulating film is provided on the second insulating film, and covers the first interconnect and the first coil. The second coil is provided on the third insulating film, and faces the first coil via the third insulating film.

A method of making a silicon-on-insulator (SOI) device from a bulk silicon substrate and an SOI device are disclosed. In the method, a stack of a heteroepitaxial layer and a silicon epitaxial layer are formed on a bulk silicon substrate, and a first photolithography process is performed on the stack to form a first trench exposing the bulk silicon substrate. The first trench is filled with a first isolation dielectric, and a second photolithography process is performed on the stack to form a second trench. The first isolation dielectric and the second trench isolate the stack. Subsequently, the heteroepitaxial layer is removed from the stack, forming at least one cavity. Moreover, the at least one cavity is filled with a buried oxide layer. The buried oxide layer and the silicon epitaxial layer overlying the buried oxide layer form SOI substrate structures. SOI devices are formed on the SOI substrate structures.

A method of making a silicon-on-insulator (SOI) device from a bulk silicon substrate and an SOI device are disclosed. In the method, a stack of a heteroepitaxial layer and a silicon epitaxial layer are formed on a bulk silicon substrate, and a first photolithography process is performed on the stack to form a first trench exposing the bulk silicon substrate. The first trench is filled with a first isolation dielectric, and a second photolithography process is performed on the stack to form a second trench. The first isolation dielectric and the second trench isolate the stack. Subsequently, the heteroepitaxial layer is removed from the stack, forming at least one cavity. Moreover, the at least one cavity is filled with a buried oxide layer. The buried oxide layer and the silicon epitaxial layer overlying the buried oxide layer form SOI substrate structures. SOI devices are formed on the SOI substrate structures.

The present invention provides a method for forming self-transformed support plates in shallow trench isolation for advanced semiconductor devices, in which after a photolithography process to define active areas on a silicon substrate, an additional photomask is implemented to add a support plate patterning layer in areas where silicon will be etched during a STI etching step to form STI trenches. Tiny silicon support plates inside the STI trenches are formed after the silicon etching. These silicon support plates may provide mechanical support to hold neighboring patterned strips where the active areas are defined or neighboring active areas islands, and preventing them from bending, deformed or shifting. An alignment of photomask pattern at following photolithography process is eased.

Methods, systems, and devices for multi-step etching in memory architectures are described. A semiconductor device may be formed based on multiple etching operations. A first set of cavities may be etched through one or more materials prior to formation of conductive materials in the semiconductor device. Each first cavity may be etched through at least a portion of a first channel and a second channel of a set of multiple channels of the semiconductor device. After a formation of the conductive materials, one or more second cavities may be etched through a portion of the first set of oxide filled cavities and a portion of the conductive materials. The one or more second cavities may complete a division of the semiconductor device into multiple subblocks.

A process can be implemented to form adjacent transistors separated by a shallow trench isolation (STI), where the STI is formed after forming gates and sources/drains of the transistors. The STI can be formed by an active area cut using a mask to form a rectangular opening for filling with a STI dielectric. Using an active area mask providing a rectangular-like shape after forming gate stacks and source/drains, a memory device can be constructed having transistors separated by a STI having a recess from active areas of the transistors by at most 50 nm.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication and, in particular, 10 nanometer node and smaller integrated circuit structure fabrication and the resulting structures. In an example, an integrated circuit structure includes a first plurality of semiconductor fins having a longest dimension along a first direction. Adjacent individual semiconductor fins of the first plurality of semiconductor fins are spaced apart from one another by a first amount in a second direction orthogonal to the first direction. A second plurality of semiconductor fins has a longest dimension along the first direction. Adjacent individual semiconductor fins of the second plurality of semiconductor fins are spaced apart from one another by the first amount in the second direction, and closest semiconductor fins of the first plurality of semiconductor fins and the second plurality of semiconductor fins are spaced apart by a second amount in the second direction.

A method includes receiving a structure that includes a substrate including a first well region having a first dopant type and a second well region having a second dopant type that is opposite to the first dopant type; and fins extending above the substrate. The method further includes forming a patterned etch mask on the structure, wherein the patterned etch mask provides an opening that is directly above a first fin of the fins, wherein the first fin is directly above the first well region. The method further includes etching the structure through the patterned etch mask, wherein the etching removes the first fin and forms a recess in the substrate that spans from the first well region into the second well region; and forming a dielectric material between remaining portions of the fins and within the recess.

The present disclosure includes a semiconductor device and a method of fabricating the same, with the semiconductor device including a substrate, a shallow trench isolation and a plurality of bit line structures. The substrate includes a plurality of active areas. The shallow trench isolation is disposed in the substrate and includes a first insulating layer and a second insulating layer. The bit line structures are disposed on the substrate. At least one of the bit line structures intersects the active areas, the first insulating layer and the second insulating layer, and respectively includes a first insulating stacked structure, a second insulating stacked structure and a third insulating stacked structure over the active areas, the first insulating layer and the second insulating layer, with each insulating stacked structure include a top surface being coplanar with each other and different stacked materials from each other.

The present disclosure provides a semiconductor device and a manufacturing method for same. The semiconductor device includes a substrate provided with: a plurality of first active structures, a first isolation structure isolating each of the first active structures, a second active structure, and second isolation structures; where each of the plurality of first active structures extends along a first direction, and the plurality of first active structures include first active segments and second active segments; the second active structure is in direct contact with the second active segments, a plurality of first trenches are opened within the second active structure in an extension direction of the first active structures, and the first trenches are located between the second active segments and an active boundary; and the second isolation structures are filled within the first trenches.