The embodiments herein relate to contact via structures of semiconductor devices and methods of forming the same. A semiconductor device is provided. The semiconductor device includes a substrate, a conductive feature, and a contact via structure. The conductive feature is over the substrate. The contact via structure is electrically coupled to the conductive feature and includes a curved concave profile throughout a height of the contact via structure and an upper width wider than the width of the conductive feature.

A semiconductor device is provided. The semiconductor device includes: a first substrate; an active pattern extending on the first substrate; a gate electrode extending on the active pattern; a source/drain region on the active pattern; a first interlayer insulating layer on the source/drain region; a sacrificial layer on the first substrate; a lower wiring layer on a lower surface of the sacrificial layer; a through via trench extending to the lower wiring layer by passing through the first interlayer insulating layer and the sacrificial layer in a vertical direction; a through via inside the through via trench and connected to the lower wiring layer; a recess inside the sacrificial layer and protruding from a sidewall of the through via trench in the second horizontal direction; and a through via insulating layer extending along the sidewall of the through via trench and into the recess.

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.

A method of fabricating a three-dimensional memory includes forming a laminated structure including stacked dummy gate layers and interlayer insulation layers on one side of a substrate. The respective adjacent dummy gate layers and interlayer insulation layers form staircase stairs. At least a part of the interlayer insulation layer of each of the staircase stairs is exposed. The method also includes forming a buffer layer covering the staircase stairs. The method further includes removing a part of the buffer layer covering the sidewalls of the staircase stairs to form spacing grooves. The method further includes forming a dielectric layer that fills the spacing grooves and covers the staircase stairs. The method further includes forming a contact hole penetrating through the dielectric layer and the buffer layer and extending to the dummy gate layer farthest from the substrate.

The present application discloses a semiconductor device with a composite barrier structure and a method for fabricating the semiconductor device. The semiconductor device includes a substrate; a first dielectric layer having a feature opening on a substrate; a composite barrier structure in the feature opening, wherein the composite barrier structure includes a barrier layer in the feature opening and an assisting blocking layer on the barrier layer; and a conductive feature on the assisting blocking layer; wherein the barrier layer comprises tantalum, and the assisting blocking layer comprises copper manganese alloy.

Spacer self-aligned via structures for gate contact or trench contact are described. In an example, an integrated circuit structure includes a plurality of gate structures above a substrate. A plurality of conductive trench contact structures is alternating with the plurality of gate structures. The integrated circuit structure also includes a plurality of dielectric spacers, a corresponding one of the plurality of dielectric spacers between adjacent ones of the plurality of gate structures and the plurality of conductive trench contact structures, wherein the plurality of dielectric spacers protrudes above the plurality of gate structures and above the plurality of conductive trench contact structures. Individual ones of the plurality of dielectric spacers have an upper spacer portion on a lower spacer portion, with an interface between the upper spacer portion and the lower spacer portion.

The present disclosure provides a semiconductor structure. The semiconductor structure includes: a substrate; a transistor on the substrate; a first dielectric layer over the transistor; a second dielectric layer over the first dielectric layer; a barrier layer extending from the second dielectric layer to the first dielectric layer; and a conductive structure separated from the second dielectric layer and the first dielectric layer by the barrier layer. The barrier layer includes: a first layer, including titanium or tantalum along inner sidewalls of the first dielectric layer and the second dielectric layer; a second layer, being an oxide of titanium or tantalum and over the first layer; and a third layer, including cobalt and over the second layer.

A semiconductor device according to one aspect includes a pad portion, an insulating layer that supports the pad portion, a first wiring layer that is formed in a layer below the pad portion and extends in a first direction below the pad portion, and a conductive member that is joined to a front surface of the pad portion and extends in a direction forming an angle of 30 to 30 with respect to the first direction. A semiconductor device according to another aspect includes a pad portion, an insulating layer that supports the pad portion, a first wiring layer that is formed in a layer below the pad portion and extends in a first direction below the pad portion, and a conductive member that is joined to a front surface of the pad portion and has a joint portion that is long in one direction in plan view and an angle of a long direction of the joint portion with respect to the first direction is 30 to 30.

Three-dimensional (3D) NAND memory devices and methods are provided. In one aspect, a fabrication method includes forming a conductor/insulator stack over a substrate, configuring memory cells through the conductor/insulator stack, forming a conductive layer, removing a portion of the conductive layer to form an opening in the conductive layer, depositing a dielectric material in a space of the opening, and forming an airgap in the space.

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.