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.

A composition for semiconductor processing includes abrasive particles, and a dishing control additive, comprising a first dishing control additive and a second dishing control additive. The first dishing control additive includes a compound having a betaine group and a salicylic group or a derivative thereof, and the second dishing control additive includes an azole-based compound. The first dishing control additive includes 0.07 parts by weight or more based on 100 parts by weight of the abrasive particles, and the second dishing control additive includes 0.13 parts by weight or less based on 100 parts by weight of the abrasive particles.

A method for manufacturing a semiconductor structure includes: forming first conducting portions that are spaced apart from each other on a base structure; forming isolation elements, each of which includes a dielectric lower portion and an etching-resistant upper portion covering the dielectric lower portion, the etching-resistant upper portion being made of an etching-resistant material different from a dielectric material of the dielectric lower portion, each of the isolation elements being isolated and exposed from two adjacent ones of the first conducting portions; sequentially forming an etch stop layer and an interlayer dielectric over the first conducting portions and the isolation elements; forming a cavity which extends through the etch stop layer and the interlayer dielectric, and which exposes one of the first conducting portions; and filling the cavity with a second conducting portion.

This disclosure relates to the process of etching and treatment of side walls while processing microdevices. One aspect is to fill the device wall indentation with a polymer. The disclosure relates to a method and device with its structure to the process of etching and treatment of sidewalls. The methods of etching, coating, and curing are used.

The present application provides a semiconductor structure and a manufacturing method of the semiconductor structure. The semiconductor structure includes a substrate, a residual nitrogen, a first dielectric layer, a plurality of first contacts, and a plurality of second contacts. The substrate includes a plurality of pillars in an array region of the substrate, wherein a top surface of each of the plurality of pillars is a substantially planar surface. The residual nitrogen is partially disposed on sidewalls of the pillars proximal to the top surfaces of the pillars. The first dielectric layer surrounds each of the pillars. The plurality of first contacts extends from the top surfaces of the pillars into the pillars. The plurality of second contacts extends from the top surface of the first dielectric layer into the first dielectric layer.

Various embodiments of fanout packages are disclosed. A method of forming a microelectronic assembly is disclosed. The method can include bonding a first surface of at least one microelectronic substrate to a surface of a carrier using a direct bonding technique without an intervening adhesive, the microelectronic substrate having a plurality of conductive interconnections on at least one surface of the microelectronic substrate. The method can include applying a molding material to an area of the surface of the carrier surrounding the microelectronic substrate to form a reconstituted substrate. The method can include processing the microelectronic substrate. The method can include singulating the reconstituted substrate at the area of the surface of the carrier and at the molding material to form the microelectronic assembly.

A method for manufacturing a semiconductor device is provided. The method includes the following. A substrate is provided. A stacked structure is formed on the substrate. The stacked structure includes first material layers and gate layers that are alternatively stacked. The stacked structure includes a giant block (GB) region and a stair-step region. A third material layer is formed on an upper surface of the GB region and an upper surface of the stair-step region. A fourth material layer filling the stair-step region and covering the GB region is formed. At least one contact structure is located in the stair-step region. Each of the at least one contact structure penetrates the third material layer and is connected with a respective one of the gate layers.

A semiconductor structure is disclosed that includes: a source feature and a drain feature disposed in a substrate; a gate structure disposed above the substrate and between the source feature and the drain feature; and a first ladder shallow trench isolation (STI) feature disposed in the substrate at least partially under the gate structure in a channel region between the source feature and the drain feature, the first ladder STI feature including a plurality of sections of different depths including a first depth section and a second depth section.

A method includes forming a metal fill material on at least one electrical connection formed in a feature formed within a dielectric layer of a semiconductor device structure. The metal fill material partially fills the feature, the partially filled feature comprises the metal fill material and an exposed first portion of a sidewall of the feature that comprises the material of the dielectric layer, and a gap region formed between a second portion of the sidewall and a sidewall of the metal fill material, and performing a soaking process on the semiconductor device structure to form a passivation layer over a surface of the metal fill material and including a portion of the metal fill material disposed within the gap.

A semiconductor device according to the present embodiment includes a wiring layer including a plurality of wires. The wires include first wires and second wires. Each of the first wires has a first width in a direction substantially parallel to the wiring layer. The second wires are arranged at wider intervals than intervals of the first wires. Each of the second wires includes a first wiring member having a second width larger than the first width, and a second wiring member provided on the first wiring member and having a third width larger than the second width.