A method is disclosed for producing an array of parallel conductive lines in a first level of a multilevel interconnect structure of a semiconductor component. The lines are produced by direct etching (a conductive layer is produced), a hardmask line pattern is formed on the conductive layer and the line pattern is transferred to the conductive layer by etching the conductive layer relative to the hardmask lines. The hardmask lines are reduced in width prior to the pattern transfer. The width reduction is done at intended via locations. Local hardmask pillars are produced on the hardmask lines prior to the width reduction step, so that the original line width is maintained at the intended via locations. As a result, the width of the conductive lines obtained after the pattern transfer is smaller compared to conventional configurations, except in local areas corresponding to the locations of interconnect vias.

Provided is a redistribution structure having reduced parasitic capacitance. The redistribution structure may include a via layer and a wiring layer disposed on the via layer in a first direction perpendicular to the via layer, the wiring layer including a metal plate and a first insulation pattern configured to penetrate the metal plate in the first direction. An outer side surface of the first insulation pattern may be exposed from a side surface of the metal plate.

A semiconductor device includes a conductive structure, a first dielectric layer, a second dielectric layer and a liner layer. The conductive structure is located on a substrate. The first dielectric layer covers the conductive structure and the substrate. The second dielectric layer is located on the first dielectric layer. An air gap is present in the first dielectric layer and the second dielectric layer, and is located above the conductive structure. The liner layer covers and surrounds a middle portion of the air gap.

A semiconductor structure and a manufacturing method thereof are provided. The manufacturing method of the semiconductor structure includes: forming a sacrificial layer in a concave in a metal layer; recessing the sacrificial layer; filling a metal-organic framework layer in the concave; and removing the sacrificial layer to form an air gap in the concave.

The present disclosure relates to a semiconductor structure and a manufacturing method, and more particularly to a 3D metal insulator metal (MIM) capacitor structure. The MIM capacitor structure includes a first capacitor electrode formed on a top surface of a substrate, a dielectric layer formed on top and side surfaces of the first capacitor electrode and on the top surface of the substrate, and a second capacitor electrode formed on top and side surfaces of the dielectric layer. The first capacitor electrode has a first width. The second capacitor electrode has a second width greater than the first width.

A method includes forming a first electrode layer having a first opening, with the first opening having a first lateral dimension, forming a first capacitor insulator over the first electrode layer, and forming a second electrode layer over the first capacitor insulator, with the second electrode layer having a second opening. The first opening is directly underlying the second opening. The second opening has a second lateral dimension greater than the first lateral dimension. The method further includes depositing a dielectric layer over the second electrode layer, and forming a contact opening, which comprises a first portion including the first opening, and a second portion including the second opening. A conductive plug is formed in the contact opening.

A semiconductor device includes a first lower epitaxial pattern on a side of a gate structure, wherein the first lower epitaxial pattern is connected to a lower active pattern; a first upper epitaxial pattern on another side of the gate structure, wherein the first upper epitaxial pattern is connected to an upper active pattern; a cut pattern that is spaced apart from the lower and upper active patterns, is adjacent the gate structure, and extends in a first direction; and a via structure connected to the first lower epitaxial pattern and the first upper epitaxial pattern in the cut pattern, wherein the via structure includes a first pillar part overlapping the first upper epitaxial pattern in a second direction, a second pillar part overlapping the first lower epitaxial pattern in the second direction, and a connecting part extending in the first direction to connect the first and second pillar parts.

A semiconductor device including a tapered spacer and method for manufacturing the same are disclosed. The semiconductor device includes a conductive-line contact plug and a conductive pattern spaced apart from each other in a first direction; a conductive line disposed over the conductive-line contact plug and extending in a second direction perpendicular to the first direction; and a spacer structure configured to contact sidewalls of the conductive line and the conductive-line contact plug, and configured such that a width of an upper portion of the spacer structure is narrower than a width of a lower portion of the spacer structure.

A method of making a semiconductor structure includes defining a first recess in an insulation layer. The method further includes forming a protection layer along a sidewall of the first recess. The method further includes forming a first conductive line in the first recess and in direct contact with the protection layer. The method further includes depositing a first insulation material over the first conductive line. The method further includes defining a second recess in the first insulation material. The method further includes forming a second conductive line in the second recess. The method further includes forming a via extending from the second conductive line, wherein the via directly contacts a sidewall of the protection layer.

Disclosed is a semiconductor package comprising a redistribution substrate and a semiconductor chip on the redistribution substrate. The redistribution substrate includes a plurality of first conductive patterns including a pair of first signal patterns that are adjacent to each other, and a plurality of second conductive patterns on surfaces of the first conductive patterns and coupled to the first conductive patterns. The second conductive patterns include a ground pattern insulated from the pair of first signal patterns. The ground pattern has an opening that penetrates the ground pattern. When viewed in plan, the pair of first signal patterns overlap the opening.