A method includes forming an anti-punch-through layer over a first region and a second region of a substrate, forming a semiconductor layer over the anti-punch-through layer, patterning the semiconductor layer and the anti-punch-through layer to form a first plurality of fins over the first region and a second plurality of fins over the second region, and forming a patterned resist layer over the first plurality of fins and the second plurality of fins. The method also includes recessing a portion of the substrate between the first plurality of fins and the second plurality of fins in an etching process through openings of the patterned resist layer.

An integrated circuit (IC) device includes a first plurality of active areas extending in a first direction and having a first pitch in a second direction perpendicular to the first direction, and a second plurality of active areas extending in the first direction, offset from the first plurality of active areas in the first direction, and having a second pitch in the second direction. A ratio of the second pitch to the first pitch is 3:2.

Structures and processes for improving radiation hardness and eliminating latch-up in integrated circuits are provided. An example process includes forming a first doped buried layer, a first well, and a second well, and using a first mask, forming a second doped buried layer only in a first region above the first doped buried layer and between at least the first well and the second well, where the first mask is configured to control spacing between the wells and the doped buried layers. The process further includes using a second mask, forming a vertical conductor located only in a second region above the first region and between at least the first well and the second well, where the vertical conductor is doped to provide a low resistance link between the second doped buried layer and at least a top surface of the substrate.

A device includes a semiconductor substrate having a first region and a second region. The device further includes a first pair of fin structures within the first region. The device further includes a second pair of fin structures within the second region. A top surface of the semiconductor surface between fin structures within the first pair is higher than a top surface of the semiconductor surface between the first pair and the second pair.

Some embodiments include an apparatus having a well region extending into a semiconductor substrate. A first conductive element is over the well region, and a second conductive element is over the first conductive element. A hole extends through the first conductive element. A connecting element extends from the second conductive element to the well region, and passes through the hole.

A method of manufacturing a semiconductor integrated circuit includes forming a body region having a second conductivity type in an upper portion of a support layer having a first conductivity type and forming a well region having a second conductivity type in an upper portion of the support layer. An output side buried layer is formed inside the body region and a circuit side buried layer is formed inside the well region. A trench is dug to penetrate through the body region and a control electrode structure is buried in the gate trench. First and second terminal regions are formed on the well region and an output terminal region is formed on the body region. An output stage element having the output terminal region is controlled by a circuit element including the first and second terminal regions.

A method of forming a semiconductor device. The method includes forming a first well of a first-type in a substrate of a second-type, forming a first active zone of the first-type in a second well of the second-type on the substrate, and forming a second active zone of the second-type in the first-type well. The method also includes forming a first pick-up region of the first-type located in the first well, and forming a second pick-up region of the second-type located in the second well. Each of the first active zone and the second active zone extends in a first direction. The first pick-up region and the second pick-up region are separated from each other, by the first active zone and the second active zone, along a direction that is different from the first direction.

Well pick-up (WPU) regions are disclosed herein for improving performance of memory arrays, such as static random access memory arrays. An exemplary integrated circuit (IC) device includes a circuit region, a WPU region, a first well extending lengthwise along a first direction through the circuit region and into the WPU region, a second well extending lengthwise along the first direction through the circuit region and into the WPU region, and a third well physically connecting a portion of the first well in the WPU region and a portion of the second well in the WPU region.

Implementations described herein provide a method that includes implanting a dopant and carbon in a portion of a substrate of a semiconductor device. The method also includes depositing a first silicon-based layer on the portion of the substrate, the first silicon-based layer reacting with the carbon to form a diffusion region on the portion of the substrate. The method further includes forming a recessed portion of the semiconductor device, the recessed portion extending through the first silicon-based layer and the diffusion region and partially extending into the portion of the substrate. The method additionally includes depositing a second silicon-based layer within the recessed portion. The method further includes etching one or more portions of the second silicon-based layer and the portion of the substrate to form a set of fin structures that include the second silicon-based layer and the portion of the substrate having the dopant and the carbon implanted.

Various implementations described herein refer to a device having a cell structure with multiple transistors including active n-type transistors and active p-type transistors disposed together within a cell boundary. The active n-type transistors may have a first diffusion region formed within the cell boundary at a first end of the cell structure. The active p-type transistors may have a second diffusion region formed within the cell boundary at a second end of the cell structure. The active p-type transistors may have a vacated region cut-out from the second diffusion region, and/or the active n-type transistors may have a vacated region cut-out from the first diffusion region.