According to some embodiments of the present disclosure, a semiconductor device includes a first power rail configured to provide a first voltage and extending in a first direction, a substrate comprising a first well having a first conductivity type and a second well having a second conductivity type, a first well tap having the first conductivity type, on the first well; a first source/drain region having the second conductivity type, on the first well; a first source/drain contact extending in a second direction and electrically connected to the first power rail, on the first source/drain region, a first connection wiring electrically connected to the first source/drain contact and extending in the first direction, and a first well contact electrically connected to the first connection wiring, on the first well tap.

An apparatus and method for efficiently routing power signals across a semiconductor die. In various implementations, an integrated circuit includes, at a first node that receives a power supply reference, a first micro through silicon via (TSV) that traverses through a silicon substrate layer to a backside metal layer. The integrated circuit includes, at a second node that receives the power supply reference, a second micro TSV that physically contacts at least one source region. The integrated circuit includes a first power rail that connects the first micro TSV to the second micro TSV. This power rail replaces contacts between the micro TSVs and a second power rail such as the frontside metal zero (M0) layer. Each of the first power rail, the second power rail, and the backside metal layer provides power connection redundancy that increases charge sharing, improves wafer yield, and reduces voltage droop.

An integrated circuit (IC) chip is provided. In one aspect, a semiconductor substrate includes active devices at its front surface and power delivery tracks on its back surface. The active devices are powered through mutually parallel buried power rails, with the power delivery tracks running transversely with respect to the power rails, and connected to the power rails by a plurality of Through Semiconductor Via connections, which run from the power rails to the back of the substrate. The TSVs are elongate slit-shaped TSVs aligned to the power rails and arranged in a staggered pattern, so that any one of the power delivery tracks is connected to a first row of mutually parallel TSVs, and any power delivery track directly adjacent to the power delivery track is connected to another row of TSVs which are staggered relative to the TSVs of the first row. A method of producing an IC chip includes producing the slit-shaped TSVs before the buried power rails.

Embodiments disclosed herein include a semiconductor structure. The semiconductor structure may include a first transistor device on a substrate, a second transistor device on the substrate, and a power rail between the first transistor device and the second transistor device. The power rail may include a first section with a first critical dimension (CD), a second section with a second CD, and a third section with a third CD.

A VTFET is provided on a wafer. A backside power delivery network is on a backside of the wafer. A first backside contact is connected to a bottom source/drain region of the VTFET and a first portion of the backside power delivery network. A second backside contact is connected to top source/drain region of the VTFET and a second portion of the backside power delivery network.

Semiconductor devices and methods of manufacturing the same are described. The method includes forming distinct and separate bottom dielectric isolation layers underneath the source/drain and underneath the gate of a gate all around device. Selectively remove of the bottom dielectric isolation layer underneath the source/drain results in better backside power rail (BPR) via alignment to the source/drain epi and reduces reliability and gate-shorting problems.

A semiconductor structure includes a stacked device structure having a first field-effect transistor having a first source/drain region, and a second field-effect transistor vertically stacked above the first field-effect transistor, the second field-effect transistor having a second source/drain region and a gate region having first sidewall spacers. The stacked device structure further includes a frontside source/drain contact disposed on a first portion of a sidewall and a top surface of the second source/drain region, a first metal via connected to the frontside source/drain contact and to a first backside power line, and second sidewall spacers disposed on a first portion of the first metal via. The first sidewall spacers comprise a first dielectric material and the second sidewall spacers comprise a second dielectric material different than the first dielectric material.

A semiconductor device includes: a channel having layers of silicon separated from each other; a metal gate in contact with the layers of silicon; source/drain regions adjacent to the metal gate; a frontside power rail extending through the layers of silicon; a dielectric separating the frontside power rail from the metal gate; a via-connect buried power rail extending through the dielectric and coupling the frontside power rail to the source/drain regions; and a backside power rail coupled to the frontside power rail. The layers of silicon are wrapped on three sides by the metal gate.

Implementations of low-resistance copper interconnects and manufacturing techniques for forming the low-resistance copper interconnects described herein may achieve low contact resistance and low sheet resistance by decreasing tantalum nitride (TaN) liner/film thickness (or eliminating the use of tantalum nitride as a copper diffusion barrier) and using ruthenium (Ru) and/or zinc silicon oxide (ZnSiO.sub.x) as a copper diffusion barrier, among other examples. The low contact resistance and low sheet resistance of the copper interconnects described herein may increase the electrical performance of an electronic device including such copper interconnects by decreasing the resistance/capacitance (RC) time constants of the electronic device and increasing signal propagation speeds across the electronic device, among other examples.

The semiconductor device includes a substrate, a stack disposed on the substrate, a first common source line and a second common source line disposed in the stack and connected to the substrate. The stack includes insulating layers and conductive layers alternately arranged. The first common source line and the second common source line are extended along a first direction and are arranged in a second direction that is perpendicular to the first direction. The first common source line includes a first segment and a second segment spaced apart by a first common source line cut. The second common source line includes a third segment and a fourth segment spaced apart by a second common source line cut. The first common source line cut is shifted relative to the second common source line cut in the first direction. A method of forming the semiconductor device is also disclosed.