There is provided a terminal that includes a first conductive layer; a wiring layer on the first conductive layer; a second conductive layer on the wiring layer; and a conductive bonding layer which is in contact with a bottom surface and a side surface of the first conductive layer, a side surface of the wiring layer, a portion of a side surface of the second conductive layer, and a portion of a bottom surface of the second conductive layer, wherein an end portion of the second conductive layer protrudes from an end portion of the first conductive layer and an end portion of the wiring layer, and wherein the conductive bonding layer is in contact with a bottom surface of the end portion of the second conductive layer.

An integrated circuit structure comprises a dielectric layer on a substrate. An open structure is in the dielectric layer, and a void-free metal-alloy interconnect is formed in the open structure, wherein the void-free metal-alloy interconnect comprise a metal-alloy comprising a combination of two or more metallic elements excluding any mixing effects of a seed layer or liner deposited in the open structure prior to a metal fill material, and excluding effects of any doping material on the metal fill material.

An embodiment includes a metal interconnect structure, comprising: a dielectric layer disposed on a substrate; an opening in the dielectric layer, wherein the opening has sidewalls and exposes a conductive region of at least one of the substrate and an interconnect line; an adhesive layer, comprising manganese, disposed over the conductive region and on the sidewalls; and a fill material, comprising cobalt, within the opening and on a surface of the adhesion layer. Other embodiments are described herein.

A semiconductor structure includes a first contact pad over an interconnect structure. The semiconductor structure further includes a second contact pad over the interconnect structure, wherein the second contact pad is electrically separated from the first contact pad. The semiconductor structure further includes a first buffer layer over the first contact pad, wherein the first buffer layer is partially over the second contact pad, and an edge of the second contact pad farthest from the first contact pad extends beyond the first buffer layer.

There is provided a terminal that includes a first conductive layer; a wiring layer on the first conductive layer; a second conductive layer on the wiring layer; and a conductive bonding layer which is in contact with a bottom surface and a side surface of the first conductive layer, a side surface of the wiring layer, a portion of a side surface of the second conductive layer, and a portion of a bottom surface of the second conductive layer, wherein an end portion of the second conductive layer protrudes from an end portion of the first conductive layer and an end portion of the wiring layer, and wherein the conductive bonding layer is in contact with a bottom surface of the end portion of the second conductive layer.

An integrated circuit chip includes a base layer. A first wiring layer is disposed on the base layer and includes a plurality of first wiring structures. A second wiring layer is disposed on the first wiring layer and includes a plurality of second wiring structures. Each of the plurality of second wiring structures has a first metal layer and a second metal layer respectively having different resistivities. A third wiring layer is disposed on the second wiring layer and includes a plurality of third wiring structures. Each of the plurality of first wiring structures comprises Ru, Mo, W, or an alloy thereof. Each of the plurality of second wiring structures comprises Ru, Mo, W, or an alloy thereof. Each of the plurality of third wiring structures comprises a material different from a material of the plurality of first wiring structures.

The present disclosure relates to method for preparing a semiconductor device with a composite landing pad. The method includes forming a first dielectric layer over a semiconductor substrate. The semiconductor device also includes forming a lower metal plug and a barrier layer in the first dielectric layer. The lower metal plug is surrounded by the barrier layer. The semiconductor device further includes forming an inner silicide portion over the lower metal plug, and an outer silicide portion over the barrier layer. A topmost surface of the outer silicide portion is higher than a topmost surface of the inner silicide portion.

Tungsten-containing metal films may be deposited in recessed features of semiconductor substrates by electrodeposition. The tungsten-containing metal film is electrodeposited under conditions so that the tunsten-containing metal film is free or substantially free of oxide. Conditions are optimized during electrodeposition for pH, tungsten concentration, and current density, among other parameters. The tungsten-containing metal film may include cobalt tungsten alloy, cobalt nickel tungsten alloy, or nickel tungsten alloy, where a tungsten content in the tungsten-containing metal film is between about 1-20 atomic %.

Embodiments herein are directed to methods of forming titanium nitride films suitable for use as a bulk fill material for conductive features in a semiconductor device, such as for capacitor electrodes and/or buried word lines in a dynamic random-access memory (DRAM) device. In one embodiment, a method of forming conductive features in a semiconductor device is provided. The method includes thermally treating a substrate surface comprising at least portions of a titanium nitride layer in the presence of hydrogen radicals. Thermally treating the substrate includes positioning the substrate in a processing volume of a processing chamber, heating the substrate to a treatment temperature of more than about 250° C., generating the hydrogen radicals using a remote plasma source fluidly coupled to the processing volume, and maintaining the substrate at the treatment temperature while concurrently exposing the at least portions of the titanium nitride layer to the generated hydrogen radicals. Here, the substrate includes a field surface having a plurality of openings formed therein and the at least portions of the titanium nitride layer are disposed in the plurality of openings.

Re-depositing of metal-containing particles of an embedded electrically conductive structure onto sidewalls of an overlying metal-containing structure is alleviated in the present application by providing a pedestal structure between the embedded electrically conductive structure and the metal-containing structure, wherein the pedestal structure has a flared sidewall that extends beyond a perimeter of the embedded electrically conductive structure. Such a pedestal structure (which can be referred to herein as a footing flare pedestal structure) mitigates, and in some embodiments, entirely eliminates, the exposure of the embedded electrically conductive structure during the patterning of metal-containing layers formed atop the embedded electrically conductive structure.