A via connection layer for an electronic package and method for fabricating a via connection layer are provided. The via connection layer includes asymmetric via(s) formed in the via connection layer. The asymmetric via include a first sidewall with a first slope angle in a first direction and a second sidewall, where the second sidewall includes a second slope angle in the first direction.

In an embodiment, a device includes: a gate structure on a channel region of a substrate; a gate mask on the gate structure, the gate mask including a first dielectric material and an impurity, a concentration of the impurity in the gate mask decreasing in a direction extending from an upper region of the gate mask to a lower region of the gate mask; a gate spacer on sidewalls of the gate mask and the gate structure, the gate spacer including the first dielectric material and the impurity, a concentration of the impurity in the gate spacer decreasing in a direction extending from an upper region of the gate spacer to a lower region of the gate spacer; and a source/drain region adjoining the gate spacer and the channel region.

A method for fabricating a semiconductor device includes: forming a dielectric layer over a substrate; forming a hole-shaped partial via in the dielectric layer; forming a line-shaped trench that partially overlaps with the partial via and has a greater line width than a line width of the partial via in the dielectric layer; forming a hole-shaped via that has a smaller line width than the line width of the partial via and penetrates the dielectric layer on a lower surface of the partial via; and gap-filling the via, the partial via and the trench with a conductive material, wherein a lower surface of the trench is positioned at a higher level than the lower surface of the partial via.

An embodiment is method including forming a first die package over a carrier substrate, the first die package comprising a first die, forming a first redistribution layer over and coupled to the first die, the first redistribution layer including one or more metal layers disposed in one or more dielectric layers, adhering a second die over the redistribution layer, laminating a first dielectric material over the second die and the first redistribution layer, forming first vias through the first dielectric material to the second die and forming second vias through the first dielectric material to the first redistribution layer, and forming a second redistribution layer over the first dielectric material and over and coupled to the first vias and the second vias.

A MOSFET includes a semiconductor body having a first side, a drift region, a body region forming a first pn-junction with the drift region, a source region forming a second pn-junction with the body region, in a vertical cross-section, a dielectric structure on the first side and having an upper side; a first gate electrode, a second gate electrode, a contact trench between the first and second gate electrodes, extending through the dielectric structure to the source region, in a horizontal direction a width of the contact trench has, in a first plane, a first value, and, in a second plane, a second value which is at most about 2.5 times the first value, and a first contact structure arranged on the dielectric structure having a through contact portion arranged in the contact trench, and in Ohmic contact with the source region.

Embodiments described herein relate generally to one or more methods for forming an interconnect structure, such as a dual damascene interconnect structure comprising a conductive line and a conductive via, and structures formed thereby. In some embodiments, an interconnect opening is formed through one or more dielectric layers over a semiconductor substrate. The interconnect opening has a via opening and a trench over the via opening. A conductive via is formed in the via opening. A nucleation enhancement treatment is performed on one or more exposed dielectric surfaces of the trench. A conductive line is formed in the trench on the one or more exposed dielectric surfaces of the trench and on the conductive via.

Embodiments described herein may be related to apparatuses, processes, and techniques related to construct via gate contact (VCG) between a metal gate of a gate structure and a metallization layer, where the VCG is split into two separate portions. The bottom portion may be oversized with respect to the metal gate and self-aligned to a trench connector in a same layer as the bottom portion of the VCG. The top portion may be an inverse taper that may be used to electrically couple the bottom portion of the VCG with the metallization layer to reduce the effects of edge placement error. Other embodiments may be described and/or claimed.

Embodiments of the disclosure are in the field of integrated circuit structure fabrication. In an example, an integrated circuit structure includes a dielectric material structure having a trench therein. A conductive interconnect line in the trench, the conductive interconnect line having a length and a width, the width having a cross-sectional profile, wherein the cross-sectional profile of the width of the conductive interconnect line has a bottom lateral width, a mid-height lateral width, and a top lateral width, and wherein the mid-height lateral width is greater than the bottom lateral width, and the mid-height lateral width is greater than the top lateral width.

A semiconductor structure includes a substrate and an interconnect. The substrate has a semiconductor device. The interconnect is disposed over the substrate and electrically coupled to the semiconductor device, and includes a metallization layer and a capping layer. The metallization layer is disposed over the substrate and includes a via portion and a line portion connecting to the via portion. The capping layer covers the line portion, where the line portion is sandwiched between the via portion and the capping layer, and the capping layer includes a plurality of sub-layers.

A method of manufacturing an array substrate is provided, which comprises: forming a first metal layer and an insulating layer in sequence on a base substrate, the insulating layer covering the first metal layer; forming an etch barrier layer on the insulating layer; etching the etching barrier layer and the insulating layer multiple times, wherein an effective blocking area of the etching barrier layer decreases successively in each etching to form a connection hole penetrating the insulating layer, the connection hole includes a plurality of via holes connected in sequence, and a slope angle of a hole wall of each via hole is smaller than a preset slope angle; and forming a second metal layer, the second metal layer being connected to the first metal layer through the connection hole.