An interconnection includes first and second conductive layers, first and second dielectric layers, a stop layer, and first and second adhesion layers is provided. The first conductive layer is disposed over a semiconductor substrate. The first dielectric layer is over the first conductive layer, and the first dielectric layer includes a via hole. The second dielectric layer is disposed over the first dielectric layer. The stop layer is located between the first dielectric layer and the second dielectric layer, and the second dielectric layer and the stop layer include a trench. The second conductive layer is located in the via hole and the trench to electrically connect with the first conductive layer. The first adhesion layer is located on sidewalls of the trench. The second adhesion layer is located between the second conductive layer and the first adhesion layer and between the second conductive layer and the first dielectric layer.

A semiconductor device is formed in such a manner that a first insulator, a first oxide semiconductor, and a first conductor are formed; the first conductor is processed to form a second conductor; the first oxide semiconductor is processed to form a second oxide semiconductor; a second insulator is formed over the second conductor; a third insulator is formed over the second insulator; a fourth insulator is formed over the third insulator; the fourth insulator, the third insulator, the second insulator, and the second conductor are selectively processed to partly expose the second oxide semiconductor; a fifth insulator is formed over the second oxide semiconductor and the fourth insulator; and a third conductor is formed over the fifth insulator and then chemical mechanical polishing treatment is performed to expose a top surface of the fourth insulator.

A field effect transistor comprising a substrate, at least one gate stack structure, source and drain regions and an interconnect structure is described. The interconnect structure comprises a metal interconnect connected to a conductive region, an adhesion sheath structure and a cap layer. The adhesion sheath structure is disposed between the metal interconnect and inter-dielectric layers and surrounds the metal interconnect. The cap layer is disposed on the metal interconnect and covers a gap between the metal interconnect and the inter-dielectric layer.

An interconnect layer is disposed over a substrate. The interconnect layer includes a plurality of dielectric segments interleaved with a plurality of metal components. A plurality of vias is disposed below, and electrically coupled to, a first group of the metal components. A plurality of dielectric components is disposed underneath a second group of the metal components. The dielectric components interleave with the vias. A conductive liner is disposed below a bottom surface and on sidewalk of the vias. A dielectric barrier layer is disposed below a bottom surface and on sidewalls of the dielectric segments. The dielectric barrier layer and the dielectric segments have different material compositions.

Some embodiments of the present disclosure provide a semiconductive device. The semiconductive device includes a first conductive layer and a second conductive layer above the first conductive layer. The second conductive layer includes a first portion and a second portion protruding from the first portion. A via structure is under the second conductive layer and on top of the first conductive layer. The via structure is substantially aligned vertically with the second portion.

A method of forming an integrated circuit that includes providing a substrate, a metal layer over the substrate, and a first dielectric layer over the metal layer. The first dielectric layer includes a via. A sidewall layer that includes a silicon compound is in the via. A second dielectric layer is over the sidewall layer and an ultra-thick metal (UTM) layer is in the via.

A semiconductor structure and a fabricating process for the same are provided. The semiconductor fabricating process includes providing a first dielectric layer, a transitional layer formed on the first dielectric layer, and a conductive fill penetrated through the transitional layer and into the first dielectric layer; removing the transitional layer; and forming a second dielectric layer over the conductive fill and the first dielectric layer.

Disclosed herein is a method including forming a first layer of a dielectric precursor composition on a substrate, the dielectric precursor composition including a silicon-containing polymeric resin, a catalyst capable of catalyzing condensation reaction of silicon-containing polymeric resin, and a photoacid generator, wherein the catalyst is deactivated by the presence of acid; exposing a portion the first layer of the dielectric precursor composition to radiation in a first image-wise manner to generate acid in the portion exposed to the radiation; heating the exposed first layer to form a cured dielectric resin in a portion of the first layer not exposed to the radiation; after heating, removing the dielectric precursor composition in the portion exposed to radiation; and filling the portion where the dielectric precursor has been removed with a metal. After cure, the cured resin of the dielectric precursor composition may include greater than 42 weight percent elemental silicon.

A method and structure for forming a local interconnect, without routing the local interconnect through an overlying metal layer. In various embodiments, a first dielectric layer is formed over a gate stack of at least one device and a second dielectric layer is formed over a contact metal layer of the at least one device. In various embodiments, a selective etching process is performed to remove the second dielectric layer and expose the contact metal layer, without substantial removal of the first dielectric layer. In some examples, a metal VIA layer is deposited over the at least one device. The metal VIA layer contacts the contact metal layer and provides a local interconnect structure. In some embodiments, a multi-level interconnect network overlying the local interconnect structure is formed.

A method and structure for forming a local interconnect, without routing the local interconnect through an overlying metal layer. In various embodiments, a first dielectric layer is formed over a gate stack of at least one device and a second dielectric layer is formed over a contact metal layer of the at least one device. In various embodiments, a selective etching process is performed to remove the second dielectric layer and expose the contact metal layer, without substantial removal of the first dielectric layer. In some examples, a metal VIA layer is deposited over the at least one device. The metal VIA layer contacts the contact metal layer and provides a local interconnect structure. In some embodiments, a multi-level interconnect network overlying the local interconnect structure is formed.