A method is presented for constructing fully-aligned top-via interconnects by employing a subtractive etch process. The method includes building a first metallization stack over a substrate, depositing a first lithography stack over the first metallization stack, etching the first lithography stack and the first metallization stack to form a receded first metallization stack, and depositing a first dielectric adjacent the receded first metallization stack. The method further includes building a second metallization stack over the first dielectric and the receded first metallization stack, depositing a second lithography stack over the second metallization stack, etching the second lithography stack and the second metallization stack to form a receded second metallization stack, and trimming the receded first metallization stack to form a via connecting the receded first metallization stack to the receded second metallization stack.

Advanced flat metals for microelectronics are provided. While conventional processes create large damascene features that have a dishing defect that causes failure in bonded devices, example systems and methods described herein create large damascene features that are planar. In an implementation, an annealing process creates large grains or large metallic crystals of copper in large damascene cavities, while a thinner layer of copper over the field of a substrate anneals into smaller grains of copper. The large grains of copper in the damascene cavities resist dishing defects during chemical-mechanical planarization (CMP), resulting in very flat damascene features. In an implementation, layers of resist and layers of a second coating material may be applied in various ways to resist dishing during chemical-mechanical planarization (CMP), resulting in very flat damascene features.

A capacitor and a method of fabricating the capacitor are provided. The capacitor includes a structure for forming a three-dimensional capacitor, the structure being a pillar structure or a trench structure; where when the structure is a pillar structure, the aspect ratio of the pillar structure is more than 10; when the structure is a trench structure, the capacitor further includes a substrate, the trench structure is formed by a material layer disposed on the surface of a base trench of the substrate, and the aspect ratio of the trench structure is more than 10. The aspect ratio of the pillar structure of the capacitor or the aspect ratio of the trench structure may be more than 10, so that the performance of the capacitor is better.

The present disclosure provides a semiconductor structure and a forming method thereof. The forming method includes forming sacrificial layers and spacer on a dielectric layer, wherein the sacrificial layers and the spacer cover the dielectric layer at the top of a gate and expose the dielectric layer on at least part of source-drain doping layers, the sacrificial layers include the first sacrificial layer located on the dielectric layer at the top of the gate, and side walls of the first sacrificial layer are provided with the spacer; after the sacrificial layers and the spacer is formed, the first sacrificial layer is removed; and the dielectric layer is etched with a patterning layer as a mask, and a first contact hole and second contact holes are formed in the dielectric layer. The embodiments and implementations of the present disclosure can avoid double graphics of the dielectric layer and the alignment error.

A manufacturing method of a semiconductor structure includes the following steps. A substrate is provided. A barrier layer is formed on the substrate. A sacrificial layer is formed on the barrier layer. An opening pattern is formed over the sacrificial layer by utilizing a photolithography process. The sacrificial layer is etched according to the opening pattern to form first trenches by using the barrier layer as an etch stop layer. A medium layer material is filled in the first trenches. The sacrificial layer is etched to form second trenches by using the barrier layer as the etch stop layer. A hard mask layer material is filled in the second trenches. The medium layer material is etched to form a hard mask layer by using the barrier layer as the etch stop layer.

Semiconductor devices and methods for forming semiconductor devices include opening at least one contact via through a sacrificial material down to contacts. Sides of the at least one contact via are lined by selectively depositing a barrier on the sacrificial material, the barrier extending along sidewalls of the at least one contact via from a top surface of the sacrificial material down to a bottom surface of the sacrificial material proximal to the contacts such that the contacts remain exposed. A conductive material is deposited in the at least one contact via down to the contacts to form stacked contacts having the hard mask on sides thereof. The sacrificial material is removed.

A semiconductor device may include a substrate; a plurality of semiconductor pillars disposed over the substrate and arranged in a first direction and a second direction crossing the first direction; an insulating layer pattern disposed between the substrate and the semiconductor pillars and extending in the second direction; a first conductive line disposed between the insulating layer pattern and the semiconductor pillars and extending in the second direction; a second conductive line formed over sidewalls of the semiconductor pillars and extending in the first direction; and a storage node disposed over each of the semiconductor pillars.

Semiconductor structure and fabrication method are provided. An exemplary method includes: providing a to-be-etched layer; forming a first mask material layer with a barrier region on the to-be-etched layer; forming a first mask groove and a second mask groove separated from each other in the first mask material layer and exposing two sidewalls of the barrier region along an extending direction of the first mask groove; forming barrier layers on exposed sidewalls of the barrier region; forming a first mask through hole in the barrier region of the first mask material layer by etching a portion of the barrier region of the first mask material layer by using the barrier layers as a mask; and forming a first groove, a second groove, and a through hole, by etching the to-be-etched layer using the barrier layers and the first mask material layer as a mask.

A line structure for fan-out circuit having a dense-line area and a fan-out area is provided. The line structure includes a plurality of dense lines arranged in the dense-line area parallel to a first direction, a plurality of pads disposed in the fan-out area, and a plurality of connecting lines arranged in the fan-out area parallel to a second direction. The connecting lines respectively connect one of the dense lines with one of the pads, wherein at least one of the connecting lines is a wavy line.

A static random-access memory structure includes a substrate, a first conductive type transistor, a second conductive type transistor and a capacitor unit. The first conductive type transistor and the second conductive type transistor are disposed on the surface of the substrate, and the capacitor unit is positioned between the transistors. The capacitor unit includes a first electrode, a second electrode, and a dielectric layer disposed between the first electrode and the second electrode. The first electrode includes a plurality of first protrudent portions and a planar portion. The first protrudent portions are connected to the first planar portion and protrude from the top surface of the planar portion. The second electrode covers the top surface of the first protrudent portions and formed between adjacent first protrudent portions.