A method for fabricating a semiconductor device including a self-aligned top via includes subtractively etching a conductive layer to form at least a first conductive line on a substrate. After the subtractive etching, the method further includes forming a barrier layer along the substate and along the first conductive line, planarizing at least portions of the barrier layer to obtain at least an exposed first conductive line, recessing at least the exposed first conductive line to form a first recessed conductive line, and forming conductive material in a via opening on the first recessed conductive line.

Embodiments of the disclosure relate to methods of selectively depositing a metal after use of a flowable polymer to protect a substrate surface within a feature. A first metal layer is deposited by physical vapor deposition (PVD). The semiconductor substrate surface is exposed to one or more monomers to form a flowable and flexible polymer film on the first metal layer within the at least one feature. The flowable polymer film forms on the first metal layer on the bottom. The one or more monomers are selected from one or more of amines with bi-functional groups, aldehydes with bi-functional groups, cyanates with bi-functional groups, ketones with bi-functional groups, and alcohols with bi-functional groups. At least a portion of the first metal layer is selectively removed from the top surface and the at least one sidewall. The flowable polymer film is removed.

The present disclosure discloses a semiconductor device and a fabrication method thereof. In the method, firstly etching a substrate in a first device region to form at least one first trench and then etching the substrate in both first device region and second device region to form at least one first isolation trench at the positions corresponding to the at least one first trench and form at least one second isolation trench in the second device region. Herein a depth of the first isolation trench is larger than that of the second isolation trench.

A semiconductor structure comprises two or more interconnect lines of a first width in a given interconnect level, and two or more interconnect lines of a second width in the given interconnect level. The two or more interconnect lines of the second width are disposed between a first one of the two or more interconnect lines of the first width and a second one of the two or more interconnect lines of the second width. The two or more interconnect lines of the first width have sidewalls with a negative taper angle. The two or more interconnect lines of the second width have sidewalls with a positive taper angle.

Metallization interconnect structures, integrated circuit devices, and methods related to high aspect ratio interconnects are discussed. A self assembled monolayer is selectively formed on interlayer dielectric sidewalls of an opening that exposes an underlying metallization structure. A first metal is formed on the underlying metallization structure and within only a bottom portion of the self assembled monolayer. The exposed portion of the self assembled monolayer is removed and a second metal is formed over the first metal.

Methods of forming patterned features on a surface of a substrate are disclosed. Exemplary methods include gas-phase formation of a layer comprising an oxalate compound on a surface of the substrate. Portions of the layer comprising the oxalate compound can be exposed to radiation or active species that form exposed and unexposed portions. Material can be selectively deposed onto the exposed or the unexposed portions.

A dielectric structure is formed over a layer than contains a conductive component. An opening is formed in the dielectric structure. The opening exposes an upper surface of the conductive component. A first deposition process is performed that deposits a first conductive layer over the dielectric structure and partially in the opening. A treatment process is performed on a first portion of the first conductive layer formed over the dielectric structure. The treatment process introduces a non-metal material to the first portion of the first conductive layer. After the treatment process has been performed, a second deposition process is performed that at least partially fills the opening with a second conductive layer without trapping a gap therein.

Semiconductor devices, and methods of their formation, are provided. The semiconductor device can include a substrate; a wiring level within the substrate; and at least one buried power rail within the wiring level, wherein the at least one buried power rail is divided into a plurality of rail segments, wherein each rail segment of the plurality of rail segments has a length smaller than a total length of the buried power rail.

The disclosed technology relates to methods for producing an interconnect structure on the back side of an integrated circuit chip. According to a first aspect, a via opening is etched in a top semiconductor layer, and filled with a sacrificial material, thereby forming a sacrificial pillar. Then front and back end of line portions are processed and the substrate is thinned. The etch stop layer and the sacrificial pillar are removed, and replaced an electrically conductive material forming a through semiconductor via. According to a second aspect, the sacrificial pillar is etched through the opening of a trench that intersects the pillar. Filling the trench with a conductive material also fills the cavity created by etching back the pillar resulting in an integral conductive pad and interconnect rail structure. The pillar can be removed and replaced by a conductive material, thereby creating the TSV connection.

A microelectronic component and a method of forming same. The microelectronic component includes: a first substrate having first through vias therein, the first substrate including silicon or glass; a first layer on a front surface of the first substrate and including one or more first dies coupled to the first through vias; a second substrate on a front surface of first layer and having second through vias therein and including silicon or glass; a second layer on a front surface of the second substrate, the first layer between the first substrate and the second substrate, the second layer including one or more second dies coupled to the second through vias; and electrically conductive structures on a back surface of the first substrate coupled to the first through vias.