A device includes a Static Random Access Memory (SRAM) array, and an SRAM cell edge region abutting the SRAM array. The SRAM array and the SRAM cell edge region in combination include first gate electrodes having a uniform pitch. A word line driver abuts the SRAM cell edge region. The word line driver includes second gate electrodes, and the first gate electrodes have lengthwise directions aligned to lengthwise directions of respective ones of the second gate electrodes.

Memory bit cells having internal node jumpers are described. In an example, an integrated circuit structure includes a memory bit cell on a substrate. The memory bit cell includes first and second gate lines parallel along a second direction of the substrate. The first and second gate lines have a first pitch along a first direction of the substrate, the first direction perpendicular to the second direction. First, second and third interconnect lines are over the first and second gate lines. The first, second and third interconnect lines are parallel along the second direction of the substrate. The first, second and third interconnect lines have a second pitch along the first direction, where the second pitch is less than the first pitch. One of the first, second and third interconnect lines is an internal node jumper for the memory bit cell.

A semiconductor structure includes a first transistor comprising a first gate structure over a first active region in a substrate. The semiconductor structure further includes a second active region in the substrate. The semiconductor structure further includes a first butted contact. The first butted contact includes a first portion extending in a first direction and overlapping the second active region, and a second portion extending from the first portion, wherein the second portion directly contacts each of a top surface and a sidewall of the first gate structure.

A semiconductor device comprising first and second unit cells, the first unit cell comprising a first fin pattern extending in a first direction, a first gate pattern extending in a second direction, and a first contact disposed on a side of the first gate pattern contacting the first fin pattern, the second unit cell comprising a second fin pattern extending in the first direction, a second gate pattern extending in the second direction, and a second contact disposed on a side of the second gate pattern contacting the second fin pattern, wherein the first and second gate patterns are spaced apart and lie on a first straight line extending in the second direction, the first and second contacts are spaced apart and lie on a second straight line extending in the second direction, and a first middle contact is disposed on and connects the first and second contacts.

A method includes forming a first fin protruding from a substrate in a first region of the substrate and a second fin protruding from the substrate in a second region of the substrate, recessing a portion of the first fin, thereby forming a first recess, recessing a portion of the second fin, thereby forming a second recess, depositing a blocking layer in the second recess, growing a base epitaxial layer in the first recess, removing the blocking layer from the second recess, and growing a doped epitaxial layer in the first recess and the second recess. The base epitaxial layer is dopant free. The doped epitaxial layer abuts the first fin in the first region and the second fin in the second region.

A semiconductor device, the device including: a first silicon layer including first single crystal silicon; an isolation layer disposed over the first silicon layer; a first metal layer disposed over the isolation layer; a second metal layer disposed over the first metal layer; a first level including a plurality of transistors, the first level disposed over the second metal layer, where the isolation layer includes an oxide to oxide bond surface, where the plurality of transistors include a second single crystal silicon region; and a third metal layer disposed over the first level, where a typical first thickness of the third metal layer is at least 50% greater than a typical second thickness of the second metal layer.

A semiconductor device includes a first PMOS transistor, a first NMOS transistor, and a second NMOS transistor connected to an output node of the first PMOS and NMOS transistors. The first PMOS transistor includes first nanowires, first source and drain regions on opposite sides of each first nanowire, and a first gate completely surrounding each first nanowire. The first NMOS transistor includes second nanowires, second source and drain regions on opposite sides of each second nanowire, and a second gate extending from the first gate and completely surrounding each second nanowire. The second NMOS transistor includes third nanowires, third source and drain regions on opposite sides of each third nanowire, and a third gate, separated from the first and second gates, and completely surrounding each third nanowire. A number of third nanowires is greater than that of first nanowires. The first and second gates share respective first and second nanowires.

The invention provides a non-volatile storage element and non-volatile storage device employing a ferroelectric material with low power consumption, excellent high reliability, and especially write/erase endurance, which can be mixed with advanced CMOS logic. The non-volatile storage element has at least a first conductive layer, a second conductive layer, and a ferroelectric layer composed of a metal oxide between both conductive layers, with a buffer layer having oxygen ion conductivity situated between the ferroelectric layer and the first conductive layer and/or second conductive layer. An interface layer composed of a single-layer film or a multilayer film may be also provided between the first conductive layer and the ferroelectric layer, the interface layer as a whole having higher dielectric constant than silicon oxide, and when the buffer layer is present between the first conductive layer and the ferroelectric layer, the interface layer is situated between the first conductive layer and the buffer layer. The non-volatile storage device comprises at least a memory cell array comprising low-power-consumption ferroelectric memory elements formed in a two-dimensional or three-dimensional configuration, and a control circuit. The ferroelectric layer is scalable to 10 nm or smaller and is fabricated at a low temperature of ≤400° C., and is subjected to low temperature thermal annealing treatment at ≤400° C. after the buffer layer has been formed, to provide high reliability.

First lithography and etching are carried out on a semiconductor structure to provide a first intermediate semiconductor structure having a first set of surface features corresponding to a first portion of desired fin formation mandrels. Second lithography and etching are carried out on the first intermediate structure, using a second mask, to provide a second intermediate semiconductor structure having a second set of surface features corresponding to a second portion of the mandrels. The second set of surface features are unequally spaced from the first set of surface features and/or the features have different pitch. The fin formation mandrels are formed in the second intermediate semiconductor structure using the first and second sets of surface features; spacer material is deposited over the mandrels and is etched back to form a third intermediate semiconductor structure having a fin pattern. Etching is carried out on same to produce the fin pattern.

Methods and systems for performing overlay and edge placement errors based on Soft X-Ray (SXR) scatterometry measurement data are presented herein. Short wavelength SXR radiation focused over a small illumination spot size enables measurement of design rule targets or in-die active device structures. In some embodiments, SXR scatterometry measurements are performed with SXR radiation having energy in a range from 10 to 5,000 electronvolts. As a result, measurements at SXR wavelengths permit target design at process design rules that closely represents actual device overlay. In some embodiments, SXR scatterometry measurements of overlay and shape parameters are performed simultaneously from the same metrology target to enable accurate measurement of Edge Placement Errors. In another aspect, overlay of aperiodic device structures is estimated based on SXR measurements of design rule targets by calibrating the SXR measurements to reference measurements of the actual device target.