Various embodiments of the present disclosure improve integration degree of semiconductor devices by simultaneously forming interconnections extending in various directions through a single gap-fill process. The embodiments of the present invention provide an interconnection structure that is capable of simplifying semiconductor processing, a semiconductor device including the interconnection structure, and a method for fabricating the semiconductor device. According to an embodiment of the present disclosure, an interconnection structure comprises: a stack of a plurality of interconnections, wherein at least two layers of the plurality of interconnections extend in different directions, and a portion of a top surface of a lower interconnection of the at least two layers is in direct contact with a portion of a bottom surface of an upper interconnection of the at least two layers.

Metal-insulator-metal (MIM) capacitor, an integrated semiconductor device having a MIM capacitor and methods of making. The MIM capacitor includes a first metal layer, a second metal layer and a dielectric layer located between the second metal layer and the first metal layer. The first metal layer, the second metal layer and the dielectric layer may be formed in a comb structure, wherein the comb structure include a first tine structure and at least a second tine structure.

The present disclosure relates to semiconductor structures and, more particularly, to a scaled gate contact and source/drain cap and methods of manufacture. The structure includes: a gate structure comprising an active region; source and drain contacts adjacent to the gate structure; a capping material over the source and drain contacts; a gate contact formed directly above the active region of the gate structure and over the capping material; a U-shape dielectric material around the gate contact, above the source and drain contacts; and a contact in direct electrical contact to the source and drain contacts.

An interconnect structure including a top via with a minimum line end extension comprises a cut filled with an etch stop material. The interconnect structure further comprises a line formed adjacent to the etch stop material. The interconnect structure further comprises a top via formed on the line adjacent to the etch stop material, wherein the top via utilizes the etch stop material to achieve minimum line extension.

A semiconductor device includes conductive structures formed in a first dielectric layer, a conductive cap layer selectively positioned over the conductive structures and the first dielectric layer with a top surface and sidewalls, a second dielectric layer selectively positioned over the first dielectric layer and disposed between the sidewalls of the conductive cap layer, a third dielectric layer selectively positioned over the second dielectric layer and disposed between the sidewalls of the conductive cap layer, a fourth dielectric layer arranged over the conductive structures and the third dielectric layer, and an interconnect structure formed in the fourth dielectric layer. The interconnect structure includes a trench structure and a via structure that is positioned below the trench structure and connected to the trench structure. The via structure includes a first portion positioned over the conductive cap layer and a second portion disposed over the first portion and the third dielectric layer.

The present application provides a semiconductor structure fabrication method, a semiconductor structure and a memory. The semiconductor structure fabrication method includes: providing a substrate, the substrate including a first surface and a second surface opposite to each other; forming a first dielectric layer on the first surface of the substrate, wherein semiconductor devices are formed in the first dielectric layer; forming first trenches extending into the substrate in the first dielectric layer; forming a first barrier layer on the first dielectric layer, the first barrier layer covering inner walls of the first trenches and a surface of the first dielectric layer; forming second trenches corresponding to the first trenches on the second surface of the substrate; and forming a second barrier layer on the substrate, the second barrier layer covering the second surface and inner walls of the second trenches.

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.

Methods and architectures for forming metal line plugs that define separations between two metal line ends, and for forming vias that interconnect the metal lines to an underlying contact. The line plugs are present in-plane with the metal lines while vias connecting the lines are in an underlying plane. One lithographic plate or reticle that prints lines at a given pitch (P) may be employed multiple times, for example each time with a pitch halving (P/2), or pitch quartering (P/4) patterning technique, to define both metal line ends and metal line vias. A one-dimensional (1D) grating mask may be employed in conjunction with cross-grating (orthogonal) masking structures that are likewise amenable to pitch splitting techniques.

A method for processing a substrate includes performing a cyclic plasma process including a plurality of cycles, each cycle of the plurality of cycles including purging a plasma processing chamber including the substrate with a first deposition gas including carbon. The substrate includes a first layer including silicon and a second layer including a metal oxide. The method further includes exposing the substrate to a first plasma generated from the first deposition gas to selectively deposit a first polymeric film over the first layer relative to the second layer; purging the plasma processing chamber with an etch gas including fluorine; and exposing the substrate to a second plasma generated from the etch gas to etch the second layer.

A method includes forming a first dielectric layer over a conductive pad, forming a second dielectric layer over the first dielectric layer, and etching the second dielectric layer to form a first opening, with a top surface of the first dielectric layer exposed to the first opening. A template layer is formed to fill the first opening. A second opening is then formed in the template layer and the first dielectric layer, with a top surface of the conductive pad exposed to the second opening. A conductive pillar is formed in the second opening.