An integrated circuit device includes a capacitor structure, wherein the capacitor structure includes: a bottom electrode over a substrate; a supporter on a sidewall of the bottom electrode; a dielectric layer on the bottom electrode and the supporter; and a top electrode on the dielectric layer and covering the bottom electrode. The bottom electrode comprises: a base electrode layer over the substrate and extending in a first direction that is perpendicular to a top surface of the substrate, and a conductive capping layer including niobium nitride that is between a sidewall of the base electrode layer and the dielectric layer, and also between a top surface of the base electrode layer and the dielectric layer.

A method of manufacturing an array of planar wafer level metal posts includes plating an array of posts within a photoresist (PR) pattern mold on a substrate of a first wafer. Stripping the PR pattern mold from the substrate and array of posts. Applying an oxide layer, at a temperature of below 150 degrees Celsius, over a surface of the first wafer. Applying chemical-mechanical polishing (CMP) to planarize the oxide layer and the array of posts.

A method which exploits the benefits of a seed enhancement layer (in terms of void-free copper fill), while preventing copper volume loss during planarization, is provided. The method includes forming a partial seed enhancement liner in a lower portion of an opening that contains a recessed copper portion. Additional copper is formed in the upper portion of the opening providing a copper structure in which no copper volume loss at the uppermost interface of the copper structure is observed.

The disclosure relates to a method of making molybdenum films utilizing boron and molybdenum nucleation layers. The resulting molybdenum films have low electrical resistivity, are substantially free of boron, and can be made at reduced temperatures compared to conventional chemical vapor deposition processes that do not use the boron or molybdenum nucleation layers. The molybdenum nucleation layer formed by this process can protect the substrate from the etching effect of MoCl.sub.5 or MoOCl.sub.4, facilitates nucleation of subsequent CVD Mo growth on top of the molybdenum nucleation layer, and enables Mo CVD deposition at lower temperatures. The nucleation layer can also be used to control the grain sizes of the subsequent CVD Mo growth, and therefore controls the electrical resistivity of the Mo film.

A method is provided for fabricating a semiconductor structure. The method includes providing a semiconductor substrate; forming an initial metal layer; simultaneously forming a plurality of discrete first metal layers and openings by etching the initial metal layer; forming a plurality of sidewalls covering the side surface of the first metal layers; and forming a plurality of second metal layers to fill the openings.

According to one embodiment, a method for manufacturing a semiconductor device is disclosed. The method includes forming a co-catalyst layer and catalyst layer above a surface of a semiconductor substrate. The co-catalyst layer and catalyst layer have fcc structure. The fcc structure is formed such that (111) face of the fcc structure is to be oriented parallel to the surface of the semiconductor substrate. The catalyst includes a portion which contacts the co-catalyst layer. The portion has the fcc structure. An exposed surface of the catalyst layer is planarized by oxidation and reduction treatments. A graphene layer is formed on the catalyst layer.

Embodiments of the present disclosure are related to improved methods for forming an interconnect structure in a substrate. In one implementation, the method includes forming a barrier layer on exposed surfaces of a feature in a dielectric layer, forming a liner layer on the barrier layer, forming a seed layer on the liner layer, forming a metal fill on the seed layer by a metal fill process and overburdening the feature using an electroplating process, performing a planarization process to expose a top surface of the dielectric layer, and selectively forming a cobalt-aluminum alloy cap layer on the barrier layer, the liner layer, the seed layer, and the metal fill by exposing the substrate to a cobalt-containing precursor and an aluminum-containing precursor.

A method of manufacturing an array of planar wafer level metal posts includes plating an array of posts within a photoresist (PR) pattern mold on a substrate of a first wafer. Stripping the PR pattern mold from the substrate and array of posts. Applying an oxide layer, at a temperature of below 150 degrees Celsius, over a surface of the first wafer. Applying chemical-mechanical polishing (CMP) to planarize the oxide layer and the array of posts.

Semiconductor device and fabrication method are provided. The method includes: providing a base substrate with a bottom metallic layer in the base substrate and a dielectric layer on the base substrate; forming interconnect openings through the dielectric layer and exposing the bottom metallic layer, where each interconnect openings includes a contacting hole and a groove on the contacting hole; forming a first conducting layer in the contacting hole, where the first conducting layer is made of a material having a first conductivity along a direction from the bottom metallic layer to a top surface of the first conducting layer; and after forming the first conducting layer, forming a second conducting layer in the groove, where the second conducting layer is made of a material having a second conductivity along a direction parallel to the top surface of the base substrate and the first conductivity is greater than the second conductivity.

A method is presented for forming an enlarged contact area. The method includes forming a trench for receiving a first conductive material, forming a noble metal cap over a portion of the first conductive material, forming a dielectric capping layer over the noble metal cap, etching a portion of the first conductive material to create a via anchoring structure and an undercut region exposing a bottom surface of the noble metal cap, and depositing a plurality of liners such that one liner of the plurality of liners directly contacts an entirety of the exposed bottom surface of the noble metal cap.