A semiconductor structure includes a power rail, a dielectric layer over the power rail, a first source/drain feature over the dielectric layer, a via structure extending through the dielectric layer and electrically connecting the first source/drain feature to the power rail, and two dielectric fins disposed on both sides of the first source/drain feature. Each of the dielectric fins includes two seal spacers, a dielectric bottom cover between bottom portions of the seal spacers, a dielectric top cover between top portions of the seal spacers, and an air gap surrounded by the seal spacers, the dielectric bottom cover, and the dielectric top cover.

A method includes: providing a substrate including a planar portion and a mesa portion over the planar portion; depositing an oxide layer over the mesa portion; depositing a ferroelectric material strip over the oxide layer and aligned with the mesa portion; and depositing a gate strip crossing the ferroelectric material strip and over the oxide layer.

A memory device structure includes a transistor structure including a gate electrode over a top surface of a fin and adjacent to a sidewall of the fin, a source structure coupled to a first region of the fin and a drain structure coupled to a second region of the fin, where the gate electrode is between the first and the second region. A gate dielectric layer is between the fin and the gate electrode. The memory device structure further includes a capacitor coupled with the transistor structure, the capacitor includes the gate electrode, a ferroelectric layer on a substantially planar uppermost surface of the gate electrode and a word line on the ferroelectric layer.

An integrated circuit (IC) device includes a power control circuit including a first transistor and a second transistor of different types. The first transistor includes a gate terminal configured to receive a control signal, a first terminal electrically coupled to a first power supply node, and a second terminal electrically coupled to a second power supply node. The second transistor includes a gate terminal configured to receive the control signal, and first and second terminals configured to receive a predetermined voltage. The first transistor is configured to, in response to the control signal, connect or disconnect the first and second power supply nodes.

A method of manufacturing an interconnect structure includes forming an opening through a dielectric layer. The opening exposes a top surface of a first conductive feature. The method further includes forming a barrier layer on sidewalls of the opening, passivating the exposed top surface of the first conductive feature with a treatment process, forming a liner layer over the barrier layer, and filling the opening with a conductive material. The liner layer may include ruthenium.

In an embodiment, a method includes forming a plurality of semiconductor fins over a substrate, the plurality of semiconductor fins comprising a first fin, a second fin, a third fin, and a fourth fin; forming a first dielectric layer over the plurality of semiconductor fins, the first dielectric layer filling an entirety of a first trench between the first fin and the second fin; forming a second dielectric layer over the first dielectric layer, the second dielectric layer filling an entirety of a second trench between the second fin and the third fin, the forming the second dielectric layer comprising: forming an oxynitride layer; and forming an oxide layer; and forming a third dielectric layer over the second dielectric layer, the third dielectric layer filling an entirety of a third trench between the third fin and the fourth fin.

Confined epitaxial regions for semiconductor devices and methods of fabricating semiconductor devices having confined epitaxial regions are described. For example, a semiconductor structure includes a plurality of parallel semiconductor fins disposed above and continuous with a semiconductor substrate. An isolation structure is disposed above the semiconductor substrate and adjacent to lower portions of each of the plurality of parallel semiconductor fins. An upper portion of each of the plurality of parallel semiconductor fins protrudes above an uppermost surface of the isolation structure. Epitaxial source and drain regions are disposed in each of the plurality of parallel semiconductor fins adjacent to a channel region in the upper portion of the semiconductor fin. The epitaxial source and drain regions do not extend laterally over the isolation structure. The semiconductor structure also includes one or more gate electrodes, each gate electrode disposed over the channel region of one or more of the plurality of parallel semiconductor fins.

A method includes forming a semiconductor fin, forming a gate stack on the semiconductor fin, and a gate spacer on a sidewall of the gate stack. The method further includes recessing the semiconductor fin to form a recess, performing a first epitaxy process to grow a first epitaxy semiconductor layer in the recess, wherein the first epitaxy semiconductor layer, and performing a second epitaxy process to grow an embedded stressor extending into the recess. The embedded stressor has a top portion higher than a top surface of the semiconductor fin, with the top portion having a first sidewall contacting a second sidewall of the gate spacer, and with the sidewall having a bottom end level with the top surface of the semiconductor fin. The embedded spacer has a bottom portion lower than the top surface of the semiconductor fin.

Semiconductor devices and methods of manufacturing are provided. In some embodiments the method includes depositing an etch stop layer over a first hard mask material, the first hard mask material over a gate stack, depositing an interlayer dielectric over the etch stop layer, forming a first opening through the interlayer dielectric, the etch stop layer, and the first hard mask material, the first opening exposing a conductive portion of the gate stack, and treating sidewalls of the first opening with a first dopant to form a first treated region within the interlayer dielectric, a second treated region within the etch stop layer, a third treated region within the first hard mask material, and a fourth treated region within the conductive portion, wherein after the treating the fourth treated region has a higher concentration of the first dopant than the first treated region.

The present disclosure provides a semiconductor device and a manufacturing method thereof, as well as a memory system. The semiconductor device includes a first semiconductor structure comprising a first well region and transistors in the first well region, and a second semiconductor structure bonded with the first semiconductor structure and including a second well region, and fin field effect transistors in the second well region. Each fin field effect transistor includes a fin structure, a gate oxide layer in contact with a top surface and side surfaces of the fin structure, and a gate layer covering the gate oxide layer.