Abstract: A one-step react-on-demand (RoD) method for fabricating flexible circuits with ultra-low sheet resistance, enhanced safety and durability. With the special functionalized substrate, a real-time three-dimensional synthesize of silver plates in micro scale was triggered on-demand right beneath the tip in the water-swelled PVA coating, forming a three-dimensional metal-polymer (3DMP) hybrid structure of ˜7 ?m with one single stroke. The as-fabricated silver traces show an enhanced durability and ultralow sheet resistance down to 4 m?/sq which is by far the lowest sheet resistance reported in literatures achieved by direct writing. Meanwhile, PVA seal small particles inside the film, adding additional safety to this technology. Since neither nanomaterials nor a harsh fabrication environment are required, the proposed method remains low-cost, user friendly and accessible to end-users.

Abstract: Provided herein is a method to printed electronics, and more particularly related to printed electronics on flexible, porous substrates. The method includes applying a coating compound comprising poly (4-vinylpyridine) (P4VP) and SU-8 dissolved in an organic alcohol solution to one or more surface of a flexible, porous substrate, curing the porous substrate at a temperature of at least 130° C. such that the porous substrate is coated with a layer of said coating compound, printing a jet of a transition metal salt catalyst solution onto one or more printing sides of the flexible, porous substrate to deposit a transition metal salt catalyst onto the one or more printing sides, and submerging the substrate in an electroless metal deposition solution to deposit the metal on the flexible, porous substrate, wherein the deposited metal induces the formation of one or more three-dimensional metal-fiber conductive structures within the flexible, porous substrate.

Abstract: A one-step react-on-demand (RoD) method for fabricating flexible circuits with ultra-low sheet resistance, enhanced safety and durability. With the special functionalized substrate, a real-time three-dimensional synthesize of silver plates in micro scale was triggered on-demand right beneath the tip in the water-swelled PVA coating, forming a three-dimensional metal-polymer (3DMP) hybrid structure of ˜7 ?m with one single stroke. The as-fabricated silver traces show an enhanced durability and ultralow sheet resistance down to 4 m?/sq which is by far the lowest sheet resistance reported in literatures achieved by direct writing. Meanwhile, PVA seal small particles inside the film, adding additional safety to this technology. Since neither nanomaterials nor a harsh fabrication environment are required, the proposed method remains low-cost, user friendly and accessible to end-users.

Abstract: A solvent-free method for fabricating conductors is disclosed. A thick patterned layer up to 13 microns containing metal precursor and reducing agent precursor are initially deposited onto a substrate using laser printing technology. The deposited patterned precursor materials are then irradiated with a newly developed high energy intense pulsed light (IPL) system in order to transform the deposited materials to thick conductive metal patterns. The easy metallization of printed patterns makes this invention an especially effective method for massive production of flexible printed circuits.

Abstract: Provided herein is a method to printed electronics, and more particularly related to printed electronics on flexible, porous substrates. The method includes applying a coating compound comprising poly (4-vinylpyridine) (P4VP) and SU-8 dissolved in an organic alcohol solution to one or more surface of a flexible, porous substrate, curing the porous substrate at a temperature of at least 130° C. such that the porous substrate is coated with a layer of said coating compound, printing a jet of a transition metal salt catalyst solution onto one or more printing sides of the flexible, porous substrate to deposit a transition metal salt catalyst onto the one or more printing sides, and submerging the substrate in an electroless metal deposition solution to deposit the metal on the flexible, porous substrate, wherein the deposited metal induces the formation of one or more three-dimensional metal-fiber conductive structures within the flexible, porous substrate.