A semiconductor device including an interleaved/nested structure of subtractive interconnects and damascene interconnects. The semiconductor device includes a subtractive-etched interconnect wiring level having subtractive interconnects and a damascene interconnect wiring level having damascene interconnects. The subtractive-etched interconnect wiring level includes first electrodes that have a first potential second electrodes that have a second potential different from the first potential, with the second electrodes generated to interleave the first electrodes. The semiconductor also includes a damascene interconnect wiring level that includes other first electrodes having the first potential, and other second electrodes having the second potential. In the damascene interconnect wiring level, the other second electrodes are also interleaved by the other first electrodes.

The semiconductor device includes a first metal layer, a second metal layer, a metal plane, a third dielectric layer and a fourth dielectric layer. The first metal layer comprises a first dielectric layer with a first plurality of signal track and a first plurality of power rails. The second metal layer comprises a second dielectric layer with a second plurality of signal tracks and a second plurality of power rails. The metal plane is between the first metal layer and the second metal layer. The third dielectric layer is between the first metal layer and the metal plane. The fourth dielectric layer is between the second metal layer and the metal plane.

An interconnection structure includes a first dielectric layer, a second dielectric layer, first wiring patterns, and a first conductive pattern. The first wiring patterns respectively include a first penetration part that extends into a surface of the first dielectric layer, a first intervention part on the first penetration part and in the second dielectric layer, and a first connection part on the first intervention part and in the second dielectric layer. A top surface of the first intervention part is at a same level as a top surface of the first conductive pattern relative to the surface of the first dielectric layer. An angle between a sidewall of the first connection part and the top surface of the first intervention part is greater than that between a sidewall of the first penetration part and a bottom surface of the first dielectric layer.

An interconnect structure including a dielectric structure, plugs, and conductive lines is provided. The dielectric structure is disposed on a substrate. The plugs are disposed in the dielectric structure. The conductive lines are disposed in the dielectric structure and are electrically connected to the plugs. The sidewall of at least one of the conductive lines is in direct contact with the dielectric structure.

IC devices with angled transistors and angled routing tracks, and related assemblies and methods, are disclosed herein. A transistor is referred to as an angled transistor if a longitudinal axis of an elongated semiconductor structure of the transistor (e.g., a fin or a nanoribbon) is neither perpendicular nor parallel to any edges of front or back sides of a support structure (e.g., a die) over which the transistor is implemented. Similarly, a routing track is referred to as an angled routing track if the routing track is neither perpendicular nor parallel to any edges of front or back faces of the support structure. Angled transistors and angled routing tracks provide a promising way to increasing densities of transistors on the limited real estate of semiconductor chips and/or decreasing adverse effects associated with continuous scaling of IC components.

Interconnect structures including signal lines, power lines and ground lines are configured for improvements in routing and scaling. Vertical stacking of the relatively wide power and ground lines allows for additional signal tracks in the same footprint of a standard cell or other electronic device. Alternatively, vertical stacking of the signal lines allows an increased number of signal tracks. Such interconnect structures are formed during back-end-of-line processing using subtractive or damascene interconnect integration techniques.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate; a first outer filling layer including a first concave portion inwardly positioned in the substrate and including a U-shaped cross-sectional profile, and a first flat portion positioned on the substrate and connecting to the first concave portion; a first center layer positioned on the first concave portion of the first outer filling layer; and a first protection layer positioned on the first center layer. A top surface of the first concave portion and a top surface of the first protection layer are substantially coplanar.

A method includes forming a first etch stop layer (ESL) over a conductive feature, forming a first dielectric layer on the first ESL, forming a second ESL on the first dielectric layer, forming a second dielectric layer on the second ESL, forming a trench in the second dielectric layer, forming a first opening in a bottom surface of the trench extending through the second dielectric layer, and forming a second opening in a bottom surface of the first opening. The second opening extends through the first dielectric layer and the first ESL. The second opening exposes a top surface of the conductive feature. The method further includes widening the first opening to a second width, filling the trench with a conductive material to form a conductive line, and filling the second opening and the first opening with the conductive material to form a conductive via.

A semiconductor device is provided. The semiconductor device comprises a semiconductor die comprising a semiconductor substrate and a plurality of transistors arranged at a front side of the semiconductor substrate. Further, the semiconductor die comprises a first electrically conductive structure extending from the front side of the semiconductor substrate to a backside of the semiconductor substrate and a second electrically conductive structure extending from the front side of the semiconductor substrate to the backside of the semiconductor substrate. The semiconductor device further comprises an interposer directly attached to the backside of the semiconductor substrate. The interposer comprises a first trace electrically connected to the first electrically conductive structure of the semiconductor die. Further the interposer comprises the first trace or a second trace electrically connected to the second electrically conductive structure of the semiconductor die.

Embodiments of the present invention are directed to processing methods and resulting structures for providing power vias through a wafer backside. In a non-limiting embodiment of the invention, a gate and a source or drain (S/D) region are formed on a substrate. A bi-layer liner is formed in a gate cut of the gate. The bi-layer liner includes a first liner on sidewalls of the gate cut and a second liner between the first liner. A top portion of the second liner is replaced with a first portion of a backside power via and the semiconductor device is flipped. A bottom portion of the second liner is replaced with a second portion of the backside power via.