In an output circuit of a semiconductor integrated circuit device, an output transistor part including a transistor connected between VSS and an output terminal has first and second active regions overlapping each other in planar view. A power line and an output line are placed in an interconnect layer on the back side so as to overlap the first and second active regions in planar view. The power line is connected to the lower face of the portion that is to be the source of the first active region through a via, and the output line is connected to the lower face of the portion that is to be the drain of the first active region through a via.

According to some embodiments of the inventive concepts, an integrated circuit device may be provided. The integrated circuit device may include a lower conductive line, a conductive via on the lower conductive line and a stopping pattern between the lower conductive line and the conductive via. A side surface of the stopping pattern may be aligned with the side surface of the lower conductive line and the side surface of the conductive via.

A memory device includes a memory cell comprising a bottom electrode, a top electrode, and a dielectric layer interposed between the bottom electrode and the top electrode. The bottom electrode has a first width W1. The top electrode has a top surface that has a second width W2 between two edges of the top surface. The memory cell has a first height H1 extending from a lower surface of the bottom electrode to the top surface of the top electrode. The memory device further includes a top contact wire coupled to the top electrode. The top contact wire has a top surface that has a third width W3, a second height H2 at a location between two adjacent memory cells, and a third height H3 extending between the top surface of the top contact wire and the insulating layer, where W1>W3>W2 and H2>H1>H3.

In certain aspects, a three-dimensional (3D) memory device includes a stack structure including interleaved conductive layers and dielectric layers and having a core array region and a staircase region in a plan view, one or more channel structures each extending through the core array region of the stack structure, and one or more contact structures each extending through the stack structure, wherein each of the one or more contact structures includes a head portion and a body portion, and a width of the head portion of the respective contact structure is larger than that of the body portion of the respective contact structure.

The present disclosure describes a method for forming an interconnect structure. The method can include forming a first layer of insulating material on a substrate, forming a via recess within the layer of insulating material, filling the via recess with a layer of conductive material, selectively growing a second layer of insulating material over the first layer of insulating material, and opening the second layer of insulating material to the layer of conductive material while growing the second layer of insulating material.

A method includes forming a fin protruding from a substrate, forming a gate structure across the fin, forming an epitaxial feature over the fin, depositing a dielectric layer covering the epitaxial feature and over sidewalls of the gate structure, performing an etching process to form a trench, the trench dividing the gate structure into first and second gate segments and extending into a region of the dielectric layer, forming a dielectric feature in the trench, recessing a portion of the dielectric feature located in the region, selectively etching the dielectric layer to expose the epitaxial feature, and depositing a conductive feature in physical contact with the epitaxial feature and directly above the portion of the dielectric feature.

A semiconductor device includes a wiring layer; a first stacked body disposed on the wiring layer; a second stacked body disposed on the first stacked body in a stacking direction; and a first resin body disposed around a periphery of the first stacked body. The first stacked body includes a first pad electrically connected to the wiring layer, a first device layer electrically connected to the first pad, and a first electrode electrically connected to the first device layer. The second stacked body includes a second pad electrically connected to the first electrode and a second device layer electrically connected to the second pad. In the stacking direction, the first resin body is vertically located closer to the wiring layer than an interface between the first stacked body and the second stacked body.

An integrated circuit structure includes a metal line that has an upper surface defining a periphery; a dielectric spacer that is formed around the periphery of the upper surface of the metal line; and a metal via that contacts the metal line and the dielectric spacer adjacent to the periphery of the upper surface. A method for making a semiconductor structure includes depositing a spacer around the periphery of an upper surface of a metal line; and depositing a via onto the metal line, so that a part of the via overlaps the spacer.

The present disclosure relates to a method of forming an interconnect structure that eliminates a separate deep via patterning process to simplify the fabrication process. In some embodiments, a first dielectric layer is formed over a first metal line and patterned to form a through-hole exposing a first contact region of the first metal line. A second dielectric layer is deposited and patterned to form a first via-hole connecting to the through-hole and a second via-hole exposing a second contact region of the second metal line from a layout view. A first via is formed on the first contact region extending to a first upper surface of the second dielectric layer, and a second via is formed on the second contact region extending to a second upper surface of the second dielectric layer.

Embodiments discloses a semiconductor structure and a fabricating method. The method includes: forming a contact hole on a substrate; forming a first doped layer on a surface of the contact hole, and annealing the first doped layer; forming at least one second doped layer on the first doped layer, and annealing each of the at least one second doped layer; and forming a third doped layer on the at least one second doped layer to fill up the contact hole. A thickness of the at least one second doped layer is greater than a thickness of the third doped layer, and the thickness of the third doped layer is greater than the thickness of the first doped layer. Annealing not only can repair lattice mismatch and lattice defect in the first doped layer/second doped layer, but also can improve surface roughness of the first doped layer/second doped layer.