In a method making a flexible electrical conductor, a mask layer (216) is applied to a substrate (210). A portion of the mask layer (216) is removed to expose the substrate (210) in an exposed shape (220) corresponding to the conductor. A liquid phase conductor (232) is applied to the portion of the substrate (210). The mask layer (216) is dissolved with a solvent (238) to leave a shaped liquid phase conductor (234) corresponding to the exposed shape on the substrate (210). A primary elastomer layer (240) is applied onto the substrate (210) and the shaped liquid phase conductor (234). The primary elastomer layer (240) and the shaped liquid phase conductor (234) are removed from the substrate (210). A secondary elastomer layer (242) is applied to the shaped liquid phase conductor (234) and the primary elastomer layer (240) to seal the shaped liquid phase conductor (234) therein.

Cables, cable connectors, and support structures for cantilever package and/or cable attachment may be fabricated using additive processes, such as a coldspray technique, for integrated circuit assemblies. In one embodiment, cable connectors may be additively fabricated directly on an electronic substrate. In another embodiment, seam lines of cables and/or between cables and cable connectors may be additively fused. In a further embodiment, integrated circuit assembly attachment and/or cable attachment support structures may be additively formed on an integrated circuit assembly.

There is provided a fabrication method of conductive nanonetworks through adaptation of a sacrificial layer includes: forming nanowire networks on a substrate; forming the sacrificial layer on a front surface of the substrate including the nanowire networks; removing the nanowire networks to expose a surface of the substrate within a region from which the nanowire networks are removed; forming a conductive material on the front surface of the substrate to fill the region, from which the nanowire networks are removed, with the conductive material while forming the conductive material on the sacrificial layer; and forming conductive nanonetworks made of the conductive material which fills the region from which the nanowire networks are removed, by removing the sacrificial layer.

A manufacturing method of an anisotropic conductive film and an apparatus thereof are provided. The manufacturing method of an anisotropic conductive film includes steps of: (a) providing a first substrate having metal contacts; (b) disposing a resin layer on the first substrate and covering the metal contacts; (c) providing a press head having a suction pattern arranged corresponding to the metal contacts; (d) sucking the conductive particles by the press head; and (e) pressing the conductive particles into the resin layer by the press head. The conductive particles are disposed corresponding to the metal contacts of the substrate, so that the problem about the short circuit between contacts can be improved, and the product yield and reliability can also be improved.

A conductive pattern having high dispersion stability and a low resistance over a board is formed. A dispersing element (1) contains a copper oxide (2), a dispersing agent (3), and a reductant. Content of the reductant is in a range of a following formula (1). Content of the dispersing agent is in a range of a following formula (2).
0.0001≤(reductant mass/copper oxide mass)≤0.10  (1)
0.0050≤(dispersing agent mass/copper oxide mass)≤0.30  (2) The dispersing element containing the reductant promotes reduction of copper oxide to copper in firing and promotes sintering of the copper.

Provided is a conductive film that can be formed without using a vacuum deposition method and includes a material that is neither a noble metal nor a special carbon material as a conductive element for exhibiting conductivity. The conductive film provided includes an arrangement portion of semiconductor nanoparticles. When a cross section including the arrangement portion is observed, the semiconductor nanoparticles are arranged in line apart from each other in the arrangement portion. A conductivity C1 measured along at least one direction is 7 S/cm or more.

A deposition apparatus that supplies mist to a front surface of an object and deposits a film made of a material substance containing the mist on the front surface of the object, the deposition apparatus comprising a mist supplying section that includes: a mist generating section that generates the mist; an inlet port that introduces the mist generated by the mist generating section into a space; and a supply port that supplies the mist from the space to the front surface of the object, wherein the supply port is provided at a different position than the inlet port in a first direction, in a first prescribed plane that includes the supply port where the first direction and a second direction intersect and that has the mist pass therethrough.

The present invention relates to a flexible electrode and a method for manufacturing the same. According to an embodiment of the present invention, the flexible electrode includes a substrate 10, a bonding layer 20 formed by adsorbing an amino group (NH.sub.2)-containing monomolecular material on the substrate 10, and a conductive layer 30 formed by coating metal nanoparticles 31 on the bonding layer 20.

A porous graphene film, its manufacturing method and an electronic product are provided. The method of manufacturing the porous graphene film includes: mixing a dispersion liquid of graphene with a dispersion liquid of particles, and performing a film-forming process to form a mixed film of graphene and particles; and removing the particles in the mixed film of graphene and particles to form the porous graphene film. The porous graphene film prepared by the method has a large specific surface area and an excellent electroconductivity.

A method of manufacturing a flexible conductive wire, a flexible conductive wire, and a display device are provided. The method manufacturing the flexible conductive wire includes: forming a zinc oxide nano-monomer into a patterned substrate, coating a carboxylated silver/3,4-ethylenedioxythiophene: polystyrenesulfonic acid solution on the patterned substrate, and curing the patterned substrate and the carboxylated silver/3,4-ethylenedioxythiophene: polystyrenesulfonic acid solution to form a flexible conductive wire. Display performance of a display panel can be improved.