Abstract: A conductive laminated structure includes a conductive layer and a thickening layer. The conductive layer extends in a first direction. The thickening layer is disposed over or under the conductive layer. The conductive laminated structure can withstand more than 40,000 folding times without breakage when a radius of curvature R is equal to 3 mm, a folding direction is perpendicular or parallel to the first direction, and a folding angle is 180°. A foldable electronic device is also provided herein.

Abstract: A touch panel includes a substrate, a plurality of peripheral traces, a plurality of marks, a touch sensing electrode, a plurality of first intermediate layers, and a plurality of second intermediate layers. The peripheral traces and the marks are disposed in a peripheral area of the substrate. The first intermediate layers are disposed between the peripheral traces and the substrate, and the second intermediate layers are disposed between the marks and the substrate. Each of the first intermediate layers and the second intermediate layers includes a metal nanowire, and the touch sensing electrode is electrically connected with the peripheral traces. A touch sensor tape is also proposed.

Abstract: A transparent heat-insulating film is provided, wherein the transparent heat-insulating film includes a base layer including a first surface and a second surface, a hard-coat layer, a silver nanowire layer, and a protective layer including an inner surface and an outer surface. The hard-coat layer and the silver nanowire layer are disposed between the first surface of the base layer and the inner surface of the protective layer. A temperature of the second surface of the base layer is T1 (° C.), a temperature of the outer surface of the protective layer is T2 (° C.), and a temperature difference between T1 and T2 (T1?T2) is ?T. When T1=50-100° C. and the base layer and the protective layer reach thermal equilibrium, ?T=0.15T1?0.35T1.

Abstract: A touch panel includes a substrate, a plurality of peripheral traces, a plurality of marks, a touch sensing electrode, a plurality of first intermediate layers, and a plurality of second intermediate layers. The peripheral traces and the marks are disposed in a peripheral area of the substrate. The first intermediate layers are disposed between the peripheral traces and the substrate, and the second intermediate layers are disposed between the marks and the substrate. Each of the first intermediate layers and the second intermediate layers includes a metal nanowire, and the touch sensing electrode is electrically connected with the peripheral traces. A touch sensor tape is also proposed.

Abstract: A transparent heat-insulating film is provided, wherein the transparent heat-insulating film includes a base layer including a first surface and a second surface, a hard-coat layer, a silver nanowire layer, and a protective layer including an inner surface and an outer surface. The hard-coat layer and the silver nanowire layer are disposed between the first surface of the base layer and the inner surface of the protective layer. A temperature of the second surface of the base layer is T1 (° C.), a temperature of the outer surface of the protective layer is T2 (° C.), and a temperature difference between T1 and T2 (T1?T2) is ?T. When T1=50-100° C. and the base layer and the protective layer reach thermal equilibrium, ?T=0.15T1?0.35T1.

Abstract: A silver nanowire (SNW) protection layer structure includes a substrate; a SNW layer, disposed on the substrate and covering only a partial region of a surface of the substrate, the SNW layer including a plurality of SNW channels; and a SNW protection layer, disposed on the SNW layer and covering a region corresponding to the plurality of SNW channels, the SNW protection layer including a light-resistant antioxidant. A manufacturing method for the SNW protection layer structure above is further provided. The SNW protection layer structure and the manufacturing method thereof are applicable in a touch sensor.

Abstract: An on-cell touch display and a preparing method thereof are provided. The on-cell touch display includes a display panel and a touch sensor disposed on the display panel. The touch sensor includes a first conductive thin film, which is formed on the display panel; an insulating layer, which is formed on the first conductive thin film; a second conductive thin film, which is formed on the insulating layer; and a protective film, which is formed on the second conductive thin film; wherein the non-uniformity value of the first conductive thin film and the second conductive thin film is less than 15% respectively.

Abstract: A stacking structure includes a substrate, a silver nanowire layer provided on a top of the substrate, and a metal layer provided on a top of the silver nanowire layer. The silver nanowire layer includes a plurality of silver nanowires and an indium tin oxide (ITO) covered on the plurality of silver nanowires. The silver nanowire layer has an overall thickness that is 2.35 to 24 times as thick as a thickness of the ITO. A touch sensor including the above described stacking structure is also disclosed.

Abstract: A method for preparing stacking structure includes providing a substrate; disposing a metallic layer and a silver nanowire layer on the substrate; applying flexographic printing technology to print an anti-etching layer on a surface of the metallic layer or the silver nanowire layer so that the anti-etching layer partially covers the metallic layer or the silver nanowire layer; applying an etching technology to remove a part of the metallic layer or the silver nanowire layer that is not covered by the anti-etching layer and the metallic layer or the silver nanowire layer disposed therebelow with an etching liquid so that the metallic layer comprises: metallic wires; a metallic grid; and a metallic plate; and removing the anti-etching layer. A stacking structure comprises: the substrate; the metallic layer; and the silver nanowire layer. The method for preparing stacking structure and the stacking structure can be applied to a touch sensor.

Abstract: A photosensitive electrically conductive structure includes: a substrate; a releasing photosensitizing resin layer disposed on the substrate; a nano silver layer disposed on the releasing photosensitizing resin layer; and a photosensitive electrically conductive layer disposed on an edge of the nano silver layer. A visible region is defined in the photosensitive electrically conductive structure where the nano silver layer is not covered by the photosensitive electrically conductive layer and a peripheral wiring region is defined in the photosensitive electrically conductive structure where the nano silver layer is covered by the photosensitive electrically conductive layer. The releasing photosensitizing resin layer has an average molecular weight (Mn) greater than 3,000 but less than 100,000, and the releasing photosensitizing resin layer, the nano silver layer, and the photosensitive electrically conductive layer are patterned.

Abstract: A stacking structure includes a substrate, a silver nanowire layer provided on a top of the substrate, and a metal layer provided on a top of the silver nanowire layer. The silver nanowire layer includes a plurality of silver nanowires and an indium tin oxide (ITO) covered on the plurality of silver nanowires. The silver nanowire layer has an overall thickness that is 2.35 to 24 times as thick as a thickness of the ITO. A touch sensor including the above described stacking structure is also disclosed.

Abstract: An optically consistent transparent conductor includes a first region and a second region. The first region includes a plurality of nanostructures. The first region has a first electrical resistivity and a first haze. The second region has a second electrical resistivity and a second haze. A difference in ratio between the first electrical resistivity and the second electrical resistivity is in a range from 5% to 9900%, and a difference in ratio between the first haze and the second haze is in a range from 2% to 500%.

Abstract: A stacking structure includes a substrate, a silver nanowire layer disposed on a top of the substrate, and a metal layer disposed on a top of the silver nanowire layer. The silver nanowire layer includes a plurality of silver nanowires and a protective coating covering the silver nanowires. The silver nanowire layer has a thickness ranging from 40 nm to 120 nm. A touch sensor including the above-described stacking structure is also disclosed.

Abstract: A method of producing a stacking structure includes providing a substrate; printing, by flexography, a catalyst layer onto the substrate, wherein the catalyst layer includes a grid pattern and a conducting wire pattern connected to the grid pattern; plating, by chemical plating, a metal layer onto the catalyst layer, wherein the metal layer includes a metal grid corresponding in position to the grid pattern of the catalyst layer and a metal conducting wire corresponding in position to the conducting wire pattern of the catalyst layer; and printing, by flexography, a silver nanowire layer onto the metal layer, wherein the silver nanowire layer at least partially overlaps the metal grid. A stacking structure includes a substrate; a catalyst layer; a metal layer; and a silver nanowire layer. The method of producing a stacking structure and the stacking structure are applicable to a touch sensor.

Abstract: A silver nanowire (SNW) protection layer structure includes a substrate; a SNW layer, disposed on the substrate and covering only a partial region of a surface of the substrate, the SNW layer including a plurality of SNW channels; and a SNW protection layer, disposed on the SNW layer and covering a region corresponding to the plurality of SNW channels, the SNW protection layer including a light-resistant antioxidant. A manufacturing method for the SNW protection layer structure above is further provided. The SNW protection layer structure and the manufacturing method thereof are applicable in a touch sensor.

Abstract: A stack structure includes: a substrate, a copper layer disposed on the substrate, a migration-proof layer disposed on the copper layer, and a silver-nanowire layer disposed on the migration-proof layer, wherein the migration-proof layer is made of materials between copper and silver in galvanic series. A touch sensor includes the stack structure.

Abstract: A transparent conductive film and a touch panel comprising the same are disclosed. The transparent conductive film comprises a substrate and a conductive mesh film disposed on the substrate. The conductive mesh film comprises a plurality of cross-bonded silver nanowires, and a rate of change of resistance of the conductive mesh film is smaller than 1% after bending the transparent conductive film over 250,000 times.

Abstract: A stacking structure preparation method includes the steps of providing a substrate; printing a silver nanowire layer on the substrate using a flexographic printing process; and printing a meal layer on the substrate and the silver nanowire layer also using the flexographic printing process. The metal layer includes a metal mesh that covers at least a part of the substrate and the silver nanowire layer, and a plurality of metal traces that is connected to the metal mesh. A stacking structure formed through the above preparation method is also disclosed. The stacking structure includes, from bottom to top, a substrate, a flexo printed silver nanowire layer, and a flexo printed metal layer partially covering the substrate and the silver nanowire layer. The above preparation method and stacking structure can be applied to the manufacturing of a touch sensor.

Abstract: A stack structure includes: a substrate, a copper layer disposed on the substrate, a migration-proof layer disposed on the copper layer, and a silver-nanowire layer disposed on the migration-proof layer, wherein the migration-proof layer is made of materials between copper and silver in galvanic series. A touch sensor includes the stack structure.

Abstract: A transparent conductive film and method for making transparent conductive film and touch panel are disclosed. The transparent conductive film includes a substrate and a conductive mesh film. The substrate has a first surface. The conductive mesh film is formed on the first surface of substrate, and the conductive mesh film includes a plurality of silver nanowires. The conductive mesh film includes a plurality of meshes, and the meshes comprise a plurality of traces and a plurality of blank areas. The sheet resistance of the conductive mesh film is 5 ?/sq to 30 ?/sq, the width of each of the traces is 1 ?m to 10 ?m, and a transparency of the conductive mesh film to visible light is greater than 85%.