Back end of line via formation for semiconductor devices and methods of fabricating the semiconductor devices. One method includes, for instance: obtaining a wafer with a substrate and at least one contact in the substrate; depositing at least one lithography stack over the substrate; performing lithography to pattern at least one via opening; depositing a block co-polymer coating over the wafer into the at least one via opening; performing an ashing to remove excess block co-polymer material and form block co-polymer caps; and performing a thermal bake to separate the block co-polymer caps into a first material and a second material. An intermediate semiconductor device is also disclosed.

The present disclosure provides one embodiment of a mask for a lithography exposure process. The mask includes a mask substrate; a first mask material layer patterned to have a first plurality of openings that define a first layer pattern; and a second mask material layer patterned to have a second plurality of openings that define a second layer pattern.

A modified trench metal-semiconductor alloy formation method involves depositing a layer of a printable dielectric or a sacrificial carbon material within a trench structure and over contact regions of a semiconductor device, and then selectively removing the printable dielectric or sacrificial carbon material to segment the trench and form plural contact vias. A metallization layer is formed within the contact vias and over the contact regions.

The present disclosure provides one embodiment of a mask for a lithography exposure process. The mask includes a mask substrate; a first mask material layer patterned to have a first plurality of openings that define a first layer pattern; and a second mask material layer patterned to have a second plurality of openings that define a second layer pattern.

Embodiments of the present disclosure generally relate to memory devices having nano-imprinted patterns interconnected to conventionally processed circuitry and a method of fabrication thereof. The memory device includes a plurality of conductive traces, a substrate having a plurality of conductive pads and a plurality of conductive posts. Each conductive pad is sized to account for alignment error inherent in the nano-imprinting process. Each conductive post is coupled between a conductive trace and a conductive pad allowing interconnection of the very finely sized features of nano-imprint lithography to the larger features of a conventionally patterned wafer.

The present disclosure provides one embodiment of a mask for a lithography exposure process. The mask includes a mask substrate; a first mask material layer patterned to have a first plurality of openings that define a first layer pattern; and a second mask material layer patterned to have a second plurality of openings that define a second layer pattern.

Disclosed is a method for manufacturing an electronic component including: forming a via hole extending in a thickness direction of a curable sealing resin layer provided on a base material by an imprint method of pressing a mold into the sealing resin layer from a side opposite to the base material; curing the sealing resin layer; filling the via hole with a conductor precursor; and forming a conductive via by heating the conductor precursor filled in the via hole.

According to an aspect of the present disclosure, a device for manufacturing a side line includes a stage on which a substrate is loaded, a side guide configured to be disposed adjacent to a side portion of the substrate loaded on the stage, and a printing unit configured to print a conductive paste on the substrate.

Discussed is a method of manufacturing a display device including forming a plurality of thin film transistors, a plurality of light emitting diodes (LEDs), a plurality of gate lines, and a plurality of data lines on a top surface of a first substrate, forming a plurality of gate link lines and a plurality of data link lines on a bottom surface of a second substrate, bonding the first substrate and the second substrate, and forming a plurality of side lines to connect the plurality of gate lines and the plurality of gate link lines, and to connect the plurality of data lines and the plurality of data link lines. The forming of the plurality of side lines includes loading the first substrate and the second substrate on a stage and disposing a side guide on side portions of the first substrate and the second substrate.

A printed structure includes a substrate comprising a substrate surface, a substrate circuit disposed in or on in a circuit area of the substrate surface, a substrate post protruding from the substrate surface exterior to the circuit area, and a component having a component top side and a component bottom side opposite the component top side. The component bottom side can be disposed on the substrate post and adhered to the substrate surface forming an air gap between the component bottom side and the substrate circuit. The substrate post can comprise a substrate post material that is a cured adhesive. Some embodiments comprise a substrate electrode and the component comprises an electrically conductive connection post extending from the component bottom side toward the substrate in electrical contact with the substrate electrode.