A transparent conductive film is disclosed. The transparent conductive film includes a substrate; a first silver nanowire layer disposed on the substrate; and a protective layer disposed on the first silver nanowire layer, wherein the protective layer is a patternable photoresist and has an identical pattern as the first silver nanowire layer.

To provide: a transparent conductive substrate containing silver nanowires and having excellent optical characteristics, electrical characteristics and light resistance; and a method for producing the same. A transparent conductive substrate characterized by comprising: a substrate; a transparent conductive film formed on at least one principal surface of the substrate, and containing a binder resin and conductive fibers; and a protective film formed on the transparent conductive film, wherein the thermal decomposition starting temperature of the binder resin is 210° C. or higher, and the protective film is a thermal-cured film obtained using a thermosetting resin.

A single-walled carbon nanotube composition includes single-walled carbon nanotubes substantially enriched in semiconducting single-walled carbon nanotubes in association with a polymer having one or more oligoether side groups. The oligoether side groups render the composition dispersable in polar organic solvents, for example alkyl carbitols, permitting formulation of ink compositions containing single-walled carbon nanotubes substantially enriched in semiconducting single-walled carbon nanotubes. Such ink compositions may be readily printed using common printing methods, such as inkjet, flexography and gravure printing.

Highly uniform and thin silver nanowires are described having average diameters below 20 nm and a small standard deviation of the diameters. The silver nanowires have a high aspect ratio. The silver nanowires can be characterized by a small number of nanowires having a diameter greater than 18 nm as well as with a blue shifted narrow absorption spectrum in a dilute solution. Methods are described to allow for the synthesis of the narrow uniform silver nanowires. Transparent conductive films formed from the thin, uniform silver nanowires can have very low levels of haze and low values of ΔL*, the diffusive luminosity, such that the transparent conductive films can provide little alteration of the appearance of a black background.

A direct patterning method of touch panel is provided. A substrate having a display region and a peripheral region is provided. A periphery circuit having a bonding pad is disposed on the periphery region. A metal nanowire layer made of metal nanowires are disposed on the display region and the peripheral region. A photosensitive pre-cured layer is disposed on the metal nanowire layer. A photolithography process is performed, which includes exposing the pre-cured layer to define a removal area and a reserved area, and removing the pre-cured layer and the metal nanowire layer on the removal area using a developer solution to form a touch-sensing electrode disposed on the display region and to expose the bonding pad disposed on the periphery region. The touch sensing electrode made of the pre-cured layer and the metal nanowire layer is electrically connected to the periphery circuit.

A method of forming a metal silicide nanowire network that includes multiple metal silicide nanowires fused together in an orderly arrangement on a substrate. The metal silicide nanowire network can be formed by printing a first set of multiple parallel silicon nanowires on the substrate and printing a second set of multiple parallel silicon nanowires over the first set of multiple parallel silicon nanowires such that said first set is perpendicular to said second set. A metal layer can be formed on the silicon nanowires. A silicidation anneal process is performed such that metal silicide nanowires are formed and fused together in an orderly arrangement, forming a grid network. After the silicidation anneal is performed, any unreacted silicon or metal can be selectively removed.

A transparent electrode member has a transparent electrode layer formed of a dispersion layer which includes a matrix and conductive nanowires dispersed therein to provide an optical adjustment region including a conductive portion having a first dispersion density and an optical adjustment portion having a second dispersion density smaller than the first dispersion density. The transparent electrode layer includes a plurality of first and second electrodes each having the optical adjustment region, and a first wire provided between and electrically connecting two adjacent first electrodes. A region of an insulating layer is formed between the first wire and the second electrodes, and between the first electrodes and the second electrodes. The first wire and a part of the first electrodes in a vicinity of the first wire are formed of a non-adjustment region of the dispersion layer including the conductive portion while lacking the optical adjustment portion.

A multi-layered electronic device including two or more stacked metal conducting layers, a dielectric layer disposed between metal conducting layers, and at least one electrical connection extending between contact pads of metal conducting layers and through a through hole of the dielectric layer is provided. A system including at least one multi-layered electronic device, a satellite coupled to at least one multi-layered electronic device, and a controller hub electrically connected to the multi-layered electronic device via the satellite is also provided. A method of manufacturing the multi-layered electronic device including forming first and second first metal conducting layers, depositing a dielectric layer adjacent to the metal conducting layers, and connecting the metal conducting layers is also provided.

A trace structure includes a substrate, at least one metal trace, and a cover. The metal trace is disposed on the substrate, and has sidewalls and a top surface. The cover is disposed on the sidewalls and the top surface of the metal trace, and the cover includes metal nanowires. The cover and the metal trace have different etch resistances.

A 3D printable feedstock ink is disclosed for use in a 3D printing process where the ink is flowed through a printing nozzle. The ink may be made up of a non-conductive flowable material and a plurality of chiplets contained in the non-conductive flowable material in random orientations. The chiplets may form a plurality of percolating chiplet networks within the non-conductive flowable material as ones of the chiplets contact one another. Each one of the chiplets has a predetermined circuit characteristic which is responsive to a predetermined electrical signal, and which becomes electrically conductive when the predetermined electrical signal is applied to the ink, to thus form at least one conductive signal path through the ink.