A semiconductor structure manufacturing method according to the embodiments of the present application includes the following steps of: providing a semiconductor substrate; forming a first reaction layer on the semiconductor substrate; forming a second reaction layer on the first reaction layer; and thermally reacting at least a portion of the first reaction layer with at least a portion of the second reaction layer, to form an amorphous diffusion barrier layer. This amorphous diffusion barrier layer is an amorphous body with no grain boundary therein. As a result, the diffusion path for metal atoms is cut off, thereby improving the barrier effect of the barrier layer efficiently and solving the circuit performance issue caused by metal atom diffusion.

A device includes a first conductive feature disposed over a substrate; a second conductive feature disposed directly on and in physical contact with the first conductive feature; a dielectric layer surrounding sidewalls of the second conductive feature; and a first barrier layer interposed between the second conductive feature and the dielectric layer and in physical contact with both the second conductive feature and the dielectric layer. The first barrier layer and the dielectric layer comprise at least two common elements.

In a contact hole of an interlayer insulating film, a tungsten film forming a contact plug is embedded via a barrier metal. The interlayer insulating film is formed by sequentially stacked HTO and BPSG films. The BPSG film has an etching rate faster than that of the HTO film with respect to a hydrofluoric acid solution used in wet etching of preprocessing before formation of the barrier metal. After the contact hole is formed in the interlayer insulating film, a width of an upper portion of the contact hole at the BPSG film is increased in a step-like shape, to be wider than a width of a lower portion at the HTO film by the wet etching before the formation of the barrier metal, whereby an aspect ratio of the contact hole is reduced. Thus, size reductions and enhancement of the reliability may be realized.

An integrated circuit (IC) device includes a line structure including a conductive line formed on a substrate and an insulation capping pattern that covers the conductive line; an insulation spacer covering a sidewall of the line structure; a conductive plug spaced apart from the conductive line in a first horizontal direction with the insulation spacer between the conductive plug and the conductive line; a conductive landing pad arranged on the conductive plug to vertically overlap the conductive plug; and a capping layer including a first portion between the conductive landing pad and the insulation capping pattern, wherein the first portion of the capping layer has a shape in which a width in the first horizontal direction gradually increases as a distance from the substrate increases between the conductive landing pad and the insulation capping pattern.

A semiconductor device includes a first substrate having an attaching surface on which first electrodes and a first insulating film are exposed, an insulating thin film that covers the attaching surface of the first substrate, and a second substrate which has an attaching surface on which second electrodes and a second insulating film are exposed and is attached to the first substrate in a state in which the attaching surface of the second substrate and the attaching surface of the first substrate are attached together sandwiching the insulating thin film therebetween, and the first electrodes and the second electrodes deform and break a part of the insulating thin film so as to be directly electrically connected to each other.

An electronic device includes a first electronic chip, a second electronic chip, and an interconnection circuit. A first region of a first surface of the first electronic chip is assembled by hybrid bonding to a third region of a third surface of the interconnection circuit. A second region of a second surface of the second electronic chip is assembled by hybrid to a fourth region of the third surface of the interconnection circuit. In this configuration, the first electronic chip is electrically coupled to the second electronic chip through the interconnection circuit. The first surface of the first electronic chip further includes a fifth region which is not in contact with the interconnection circuit. This fifth region includes a connection pad electrically connected by a connection element to a connection substrate to which the interconnection circuit is mounted.

A multi-layer interconnect structure with a self-aligning barrier structure and a method for fabricating the same is disclosed. For example, the method includes forming a via through an interlayer dielectric (ILD) layer, an etch stop layer (ESL), and a contact structure, pre-cleaning the via with a metal halide, forming a barrier structure on the contact structure in-situ during the pre-cleaning of the via with the metal halide, and depositing a second metal in the via on top of the barrier structure.

Provided herein are low resistance metallization stack structures for logic and memory applications and related methods of fabrication, The methods involve forming bulk conductive films on thin low resistivity transition metal layers that have large grain size. The bulk conductive films follow the grains of the low resistivity transition metal films, resulting in large grain size. Also provided are devices including template layers and bulk films.

Compositions of matter, compounds, articles of manufacture and processes to reduce or substantially eliminate EM and/or stress migration, and/or TDDB in copper interconnects in microelectronic devices and circuits, especially a metal liner around copper interconnects comprise an ultra thin layer or layers of Mn alloys containing at least one of W and/or Co on the metal liner. This novel alloy provides EM and/or stress migration resistance, and/or TDDB resistance in these copper interconnects, comparable to thicker layers of other alloys found in substantially larger circuits and allows the miniaturization of the circuit without having to use thicker EM and/or TDDB resistant alloys previously used thereby enhancing the miniaturization, i.e., these novel alloy layers can be miniaturized along with the circuit and provide substantially the same EM and/or TDDB resistance as thicker layers of different alloy materials previously used that lose some of their EM and/or TDDB resistance when used as thinner layers.

A device relates to a semiconductor device. The semiconductor device includes a narrow-line bamboo microstructure integrated within a metal layer of the semiconductor device and a narrow-line polycrystalline microstructure. The narrow-line polycrystalline microstructure is integrated within the same metal layer as the narrow-line bamboo microstructure.