A method for forming an interconnection structure for a semiconductor device is provided. The method includes: (i) forming a conductive layer on an insulating layer; (ii) forming above the conductive layer a first set of mandrel lines of a first material; (iii) forming a set of spacer lines of a second material different from the first material, wherein the spacer lines of the second material are formed on sidewalls of the first set of mandrel lines; (iv) forming a second set of mandrel lines of a third material different from the first and second materials, wherein the second set of mandrel lines fill gaps between spacer lines of the set of spacer lines; (v) cutting at least a first mandrel line of the second set of mandrel lines into two line segments separated by a gap by etching said first mandrel line of the second set of mandrel lines selectively to the set of spacer lines and the first set of mandrel lines, cutting at least a first mandrel line of the first set of mandrel lines into two line segments separated by a gap by etching said first mandrel line of the first set of mandrel lines selectively to the set of spacer lines and the second set of mandrel lines; (vi) removing the set of spacer lines, selectively to the first and second sets of mandrel lines, thereby forming an alternating pattern of mandrel lines of the first set of mandrel lines and mandrel lines of the second set of mandrel lines; and (vii) patterning the conductive layer to form a set of conductive lines, wherein the patterning comprises etching while using the alternating pattern of mandrel lines of the first and second sets of mandrel lines as an etch mask.

A first memory film and a sacrificial fill structure are formed within each first-tier memory opening through a first alternating stack of first insulating layers and first spacer material layers. A second alternating stack of second insulating layers and second spacer material layers is formed over the first alternating stack, and a second-tier memory opening is formed over each sacrificial fill structure. A second memory film is formed in each upper opening, and the sacrificial fill structures are removed from underneath the second-tier memory openings to form memory openings. A semiconductor channel is formed on each vertically neighboring pair of a first memory film and a second memory film as a continuous layer. The first memory film is protected by the sacrificial fill structure during formation of the second-tier memory openings.

In one example aspect, the present disclosure is directed to a method. The method includes receiving a workpiece having a conductive feature over a semiconductor substrate, forming a sacrificial material layer over the conductive feature, removing first portions of the sacrificial material layer to form line trenches and to expose a top surface of the conductive feature in one of the line trenches; forming line features in the line trenches, removing second portions of the sacrificial material layer to form gaps between the line features, and forming dielectric features in the gaps, the dielectric features enclosing an air gap.

Methods for asymmetric deposition of a material on a structure formed on a substrate are provided herein. In some embodiments, a method for asymmetric deposition of a material includes forming a plasma from a process gas comprising ionized fluorocarbon (CxFy) particles, depositing an asymmetric fluorocarbon (CxFy) polymer coating on a first sidewall and a bottom portion of an opening formed in a first dielectric layer using angled CxFy ions, depositing a metal, metallic nitride, or metallic oxide on a second sidewall of the opening, and removing the CxFy polymer coating from the first sidewall and the bottom portion of the opening to leave an asymmetric deposition of the metal, metallic nitride, or metallic oxide on the structure.

In an example, there is disclosed an integrated circuit, having: a first layer having a dielectric, a first conductive interconnect and a second conductive interconnect; a second layer having a third conductive interconnect; a conductive via between the first layer and the second layer to electrically couple the second conductive interconnect to the third conductive interconnect; and an etch-resistant plug disposed vertically between the first layer and second layer and disposed to prevent the via from electrically shorting to the first conductive interconnect.

A capacitor and a method of fabricating the capacitor are provided. The capacitor includes a structure for forming a three-dimensional capacitor, the structure being a pillar structure or a trench structure; where when the structure is a pillar structure, the aspect ratio of the pillar structure is more than 10; when the structure is a trench structure, the capacitor further includes a substrate, the trench structure is formed by a material layer disposed on the surface of a base trench of the substrate, and the aspect ratio of the trench structure is more than 10. The aspect ratio of the pillar structure of the capacitor or the aspect ratio of the trench structure may be more than 10, so that the performance of the capacitor is better.

A compound semiconductor solar cell and a method of manufacturing the same are disclosed. The method for fabricating a compound semiconductor solar cell comprises forming a first mask layer on a front surface of a compound semiconductor layer of a second region which is a region other than a first region where the front electrode is to be formed; forming a seed metal layer on the front surface of the compound semiconductor layer of the first region and on the first mask layer of the second region; removing the seed metal layer over the first mask layer and the first mask layer; removing a part of the compound semiconductor layer of the second region from the front surface of the compound semiconductor layer by using the seed metal layer of the first region as a mask; forming a second mask layer on the compound semiconductor layer of the second region; forming an electrode metal layer on the seed metal layer not covered by the second mask layer; and removing the second mask layer.

A field-effect transistor (FET) and method of manufacture thereof include patterning a mask above a source and drain of a FET to form holes in the mask, growing epitaxial structures from the holes in the mask, and growing a doped epitaxial shell to coat sidewalls of the epitaxial structures.

A field-effect transistor (FET) and method of manufacture thereof include a gate, a doped semiconductor structure formed on top of the planar source and drain regions, and a sheath of conducting materials flanking the formed doped semiconductor structure, where the sheath is perpendicular to a surface of the planar source and drain regions.

A first memory film and a sacrificial fill structure are formed within each first-tier memory opening through a first alternating stack of first insulating layers and first spacer material layers. A second alternating stack of second insulating layers and second spacer material layers is formed over the first alternating stack, and a second-tier memory opening is formed over each sacrificial fill structure. A second memory film is formed in each upper opening, and the sacrificial fill structures are removed from underneath the second-tier memory openings to form memory openings. A semiconductor channel is formed on each vertically neighboring pair of a first memory film and a second memory film as a continuous layer. The first memory film is protected by the sacrificial fill structure during formation of the second-tier memory openings.