Abstract: An imprinted optical micro-channel structure for transmitting light to an optical receiver or receiving light from an optical transmitter includes a substrate and a cured optical layer formed in relation to the substrate. The cured optical layer includes one or more optical micro-channels imprinted in the cured optical layer. Each optical micro-channel includes a cured light-transparent material forming a light-pipe that transmits light in the optical micro-channel. The optical transmitter is located in alignment with a light-pipe for transmitting light through the light-pipe or the optical receiver is located in alignment with a light-pipe for receiving light from the light-pipe.

Abstract: A method of making a multi-layer micro-wire structure includes providing a substrate having a surface and forming a plurality of micro-channels in the surface. A first material composition is located in a first layer only in each micro-channel and not on the surface. A second material composition different from the first material composition is located in a second layer different from the first layer only in each micro-channel and not on the surface. The first material composition in the first layer and the second material composition in the second layer form an electrically conductive multi-layer micro-wire in each micro-channel.

Abstract: A method of making an imprinted optical micro-channel structure for transmitting light to an optical receiver or receiving light from an optical transmitter includes forming a curable optical layer over a substrate and imprinting one or more optical micro-channels in the optical layer with a first stamp. The curable optical layer is cured to form a cured optical layer having the optical micro-channels imprinted in the cured optical layer. A curable light-transparent material is located in the optical micro-channels and cured to form light-pipes of cured light-transparent material in the optical micro-channels. The optical transmitter located in alignment with a light-pipe for transmitting light through the light-pipe or the optical receiver is located in alignment with a light-pipe for receiving light from the light-pipe.

Abstract: A method of making an imprinted micro-wire structure includes providing a substrate, a first stamp, and a different multi-level second stamp. A curable bottom layer is provided over the substrate. One or more bottom-layer micro-channel(s) are imprinted in the curable bottom layer with the first stamp and a bottom-layer micro-wire formed in each bottom-layer micro-channel. A curable multi-layer is formed adjacent to and in contact with the cured bottom layer. First and second multi-layer micro-channels and a top-layer micro-channel are imprinted in the curable multi-layer with the multi-level second stamp. Either two bottom-layer micro-wires are electrically connected through the first and second multi-layer micro-wires and a top-layer micro-wire or two top-layer micro-wires are electrically connected through the first and second multi-layer micro-wires and a bottom-layer micro-wire.

Abstract: A method of making a folded micro-wire substrate structure includes providing a transparent flexible substrate having a first side and a second side opposed to the first side. The flexible substrate has a first portion and a second portion adjacent to the first portion of the flexible substrate. One or more electrical conductors and one or more electrical components are formed on or in the flexible substrate. At least one optical element is formed on or in the flexible substrate in the second portion. The flexible substrate is folded with a first fold between the first and second portions so that the first portion is aligned with the second portion in a perpendicular direction and the optical element directs light to or from the electrical component.

Abstract: A folded micro-wire substrate structure includes a folded flexible substrate having a first side and a second side opposed to the first side. The flexible substrate has a first portion, a second portion adjacent to the first portion, and a third portion adjacent to the second portion so that the second portion is between the first and third portions of the flexible substrate. The flexible substrate has at least a first fold between the first and second portions so that the first portion is adjacent to the second portion in a perpendicular direction. The flexible substrate has at least a second fold between the second and third portions so that the second side is between the second and third portions in the perpendicular direction and one or more electrical conductors are located in or on the flexible substrate.

Abstract: A folded micro-wire substrate structure includes a transparent folded flexible substrate having a first side and a second side opposed to the first side. The flexible substrate has a first portion and a second portion adjacent to the first portion of the flexible substrate. The flexible substrate has at least a first fold between the first and second portions so that the first portion is aligned with the second portion in a perpendicular direction. One or more electrical conductors is located in or on the flexible substrate, at least one electrical component is located on or in the flexible substrate in the first portion. At least one optical element is located on or in the flexible substrate in the second portion located so that the optical element directs light to or from the electrical component.

Abstract: A method of making a folded micro-wire substrate structure includes providing a flexible substrate and first, second, and third portions. One or more electrical conductors are formed on or in the flexible substrate. The flexible substrate is folded with a first fold between the first and second portions so that the first portion is located adjacent to the second portion in a perpendicular direction. The flexible substrate is folded with at least a second fold between the second and third portions so that the second side is between the second portion and the third portion in the perpendicular direction. The folded flexible substrate is secured to form the folded micro-wire substrate structure.

Abstract: Electrically-conductive articles are prepared to have electrically-conductive silver metal electrode grids and electrically-conductive silver connector wire patterns (BUS lines) on one or both supporting sides of a transparent substrate. The electrically-conductive silver connector wire patterns are designed with at least one silver main wire that comprises two or more adjacent silver micro-wires in bundled patterns. These bundled patterns and silver micro-wires are designed with specific dimensions and configurations to provide optimal fidelity (or correspondence) to the mask image used to provide such images in a silver halide emulsion layer. The electrically-conductive articles are provided by imagewise exposure, development, and fixing of corresponding silver halide-containing conductive film element precursors containing photosensitive silver halide emulsion layers. The electrically-conductive articles can be used are parts of various electronic devices including touch screen devices.

Abstract: Electrically-conductive articles are prepared to have electrically-conductive silver metal electrode grids and electrically-conductive silver connector wire patterns (BUS lines) on one or both supporting sides of a transparent substrate. The electrically-conductive silver connector wire patterns are designed with at least one silver main wire that comprises two or more adjacent silver micro-wires in bundled patterns. These bundled patterns and silver micro-wires are designed with specific dimensions and configurations to provide optimal fidelity (or correspondence) to the mask image used to provide such images in a silver halide emulsion layer. The electrically-conductive articles are provided by imagewise exposure, development, and fixing of corresponding silver halide-containing conductive film element precursors containing photosensitive silver halide emulsion layers. The electrically-conductive articles can be used are parts of various electronic devices including touch screen devices.

Abstract: Electrically-conductive articles are prepared to have electrically-conductive silver metal electrode grids and electrically-conductive silver connector wire patterns (BUS lines) on one or both supporting sides of a transparent substrate. The electrically-conductive silver connector wire patterns are designed with one silver main wire that comprises two or more adjacent silver micro-wires in bundled patterns. These bundled patterns and silver micro-wires are designed with specific dimensions and configurations to provide optimal fidelity (or correspondence) to the mask image used to provide such images in a silver halide emulsion layer. The electrically-conductive articles are provided by imagewise exposure, development, and fixing of corresponding silver halide-containing conductive film element precursors containing photosensitive silver halide emulsion layers. The electrically-conductive articles can be used as parts of various electronic devices including touch screen devices.

Abstract: A folded micro-wire substrate structure includes a transparent folded flexible substrate having a first side and a second side opposed to the first side. The flexible substrate has a first portion and a second portion adjacent to the first portion of the flexible substrate. The flexible substrate has at least a first fold between the first and second portions so that the first portion is aligned with the second portion in a perpendicular direction. One or more electrical conductors is located in or on the flexible substrate, at least one electrical component is located on or in the flexible substrate in the first portion. At least one optical element is located on or in the flexible substrate in the second portion located so that the optical element directs light to or from the electrical component.

Abstract: A method of making an imprinted multi-layer structure includes providing a support and locating a first curable layer including a first material on or over the support. A second curable layer including a second material different from the first material is located on or over the first curable layer. The first curable layer and the second curable layer are imprinted in a single step with an imprinting stamp having a structure with a depth greater than the thickness of the second curable layer. The first curable layer and the second curable layer are cured in a single step to form a first cured layer and a second cured layer. The imprinting stamp is removed to form an imprinted multi-layer structure with a depth greater than the thickness of the second cured layer.

Abstract: A multi-layer micro-wire structure resistant to cracking including a substrate having a surface, one or more micro-channels formed in the substrate, an electrically conductive first material composition forming a first layer located in each micro-channel, and an electrically conductive second material composition having a greater tensile ductility than the first material composition forming a second layer located in each micro-channel, the first material composition and the second material composition in electrical contact to form an electrically conductive multi-layer micro-wire in each micro-channel, whereby the multi-layer micro-wire is resistant to cracking

Abstract: A method of making a multi-layer micro-wire structure resistant to cracking on a substrate having a surface including forming a plurality of micro-channels in the substrate, locating a first electrically conductive material composition forming a first layer in each micro-channel, and locating a second electrically conductive material composition having a greater tensile ductility than the first material composition to form a second layer in each micro-channel and in electrical contact with the first electrically conductive material composition thereby providing an electrically conductive multi-layer micro-wire in each micro-channel that is resistant to cracking.

Abstract: A method of making a thin-film multi-layer micro-wire structure includes providing a substrate and a layer on the substrate with one or more micro-channels having a width less than or equal to 20 microns. A conductive material including silver nano-particles and having a percent ratio of silver that is greater than or equal to 40% by weight is located in the micro-channels and cured to form an electrically conductive micro-wire. The electrically conductive micro-wire has a width less than or equal to 20 microns and a depth less than or equal to 20 microns. Each micro-wire is electrolessly plated to form a plated layer located at least partially within each micro-channel between the micro-wire and the layer surface in electrical contact with the micro-wire. The plated layer has a thickness less than a thickness of the micro-wire so that the micro-wire and plated layer form the thin-film multi-layer micro-wire.

Abstract: A thin-film multi-layer micro-wire structure includes a substrate and a layer located on the substrate or forming a part of the substrate. One or more micro-channels are located in the layer. Each micro-channel has a width less than or equal to 20 microns. A cured electrically conductive micro-wire is located only within each micro-channel. The micro-wire has a thickness less than or equal to 20 microns, including silver nano-particles, and having a percent ratio of silver that is greater than or equal to 40% by weight. An electrolessly plated layer is located at least partially within each micro-channel between the micro-wire and the layer surface and in electrical contact with the micro-wire. The plated layer has a thickness less than a thickness of the micro-wire so that the micro-wire and plated layer form the thin-film multi-layer micro-wire.

Abstract: A micro-wire circuit structure adapted for wrapping includes a display and a flexible substrate. The flexible substrate includes a plurality of electrically conductive micro-wires formed on, in, or adjacent to a common side of the flexible substrate. One or more electrical circuits is located on or in a circuit portion of the flexible substrate and electrically connect to corresponding micro-wire electrodes in a touch portion of the flexible substrate. The flexible substrate is located in relation to the display with the touch portion located adjacent to a display viewing side, the circuit portion located adjacent to a display back side, and an edge portion of the flexible substrate wrapping around a display edge side from the display viewing side to the display back side.

Abstract: A method of making a micro-wire circuit structure adapted for wrapping includes providing a display and a flexible substrate. The flexible substrate includes a plurality of electrically conductive micro-wires on, in, or adjacent to a common side of the flexible substrate and forming micro-wire electrodes in a touch portion of the flexible substrate. One or more electrical circuits is located on or in a circuit portion of the flexible substrate and one or more micro-wires electrically connects the one or more electrical circuits to corresponding micro-wire electrodes. The flexible substrate is located in relation to the display with the touch portion located adjacent to a display viewing side, the circuit portion located adjacent to a display back side, and an edge portion of the flexible substrate wrapping around a display edge from the display viewing side to the display back side.

Abstract: An electronic sensing system has a transceiver with input and output pads, an excitation circuit connected to the output pad, and a detection circuit connected to the input pad. An electrically-conductive sensor patch has an electrical state that changes with exposure to a corresponding environmental factor. The detection circuit detects an electrical state of the input electrical-connection pad in response to the excitation signal and the electrical state of the input pad. Several electrically-conductive sensor patches are distributed over the substrate so that they are exposed to an external environmental factor substantially contemporaneously, each having a conductance susceptible to a respective environmental factor. The output pad is electrically connected to the input pad through the sensor patches in series, so that the detection circuit detects an electrical state of the input pad in response to the excitation signal and the respective conductances of the sensor patches.