An electromagnetic interference (EMI) shielded device which includes an object to be shielded and an EMI shielding material encompassing the object. The EMI shielding material is made up of, but not limited to a broadband biopolymer or polymer dissolved in organic solvents and shielding guest material. The specific makeup of the shielding material and fabrication procedure of the shielding material is also included herein.

Systems and methods that enable printing of conformal materials and other waterproof coating materials at high resolution. An initial printing of a material on edges of a component is performed at high resolution in a first printing step, and a subsequent printing of the material on remaining surfaces of the component is applied in a second printing step, with or without curing of the material printed on the edges between the two printing steps. The printing of the material may be performed by a laser-assisted deposition or using another dispensing system to achieve a high resolution printing of the material and a high printing speed.

An aspect of the present invention relates to a conductive resin composition containing an epoxy resin, a curing agent, and a conductive powder, in which a loss modulus of a dried product or semi-cured product of the conductive resin composition at 170° C. is 0.1 MPa or more and 15 MPa or less.

A method of preparing a conductive silver pattern on a substrate comprising the steps of: applying a silver ink on the substrate to form a silver pattern, and sintering the applied silver pattern in one step at a temperature of at least 50° C. and a relative humidity (RH) of at least 50%.

Methods and systems suitable for fabricating multi-layer elastic electronic devices, and elastic electronic devices formed thereby. A method of fabricating an elastomer-based electronic device includes printing a first liquid material and then a second liquid material on a fabric substrate that comprises fibers. The first and second liquid materials are sequentially printed with a three-dimensional printer that directly prints the first liquid material onto the fabric substrate so that the first liquid material wicks through some of the fibers of the fabric substrate and forms a solid matrix of an elastomer-based composite that comprises the matrix and the fabric substrate, after which the three-dimensional printer directly prints the second liquid material on the elastomer-based composite to form a film thereon. The elastomer-based composite and film are electrical components of the elastomer-based electronic device.

Provided is a wiring board including a fine-wire pattern made of cured conductive ink formed on a board surface, wherein assuming that two orthogonal directions on the board surface are directions X and Y, a line width of another fine wire that is included in the fine-wire pattern, passes through another point on the board surface not aligned in the direction X but aligned in the direction Y with one intersection where three or more fine wires included in the fine-wire pattern are centered at one spot, and does not form another intersection where three or more fine wires are centered at one spot at said another point is 1.5 times or more a minimum line width of the fine wires included in the fine-wire pattern.

An aspect of the invention provides a multilayer circuit substrate that has a simple configuration and is thin. The multilayer circuit substrate has a stacked multiple of substrates and a wiring pattern disposed so to be sandwiched between the stacked multiple of substrates. At least one portion of the wiring pattern is configured of a conductive material wherein conductive particles are sintered. An upper face of the wiring pattern is directly joined to the substrate positioned above the wiring pattern, a lower face of the wiring pattern is directly joined to the substrate positioned below the wiring pattern, and the stacked multiple of substrates are fixed to each other by the wiring pattern.

The disclosure generally relates to a method of creating patterned metallic circuits (e.g., silver circuits) on a substrate (e.g., a ceramic substrate). A porous metal interlayer (e.g., porous nickel) is applied to the substrate to improve wetting and adhesion of the patterned metal circuit material to the substrate. The substrate is heated to a temperature sufficient to melt the patterned metal circuit material but not the porous metal interlayer. Spreading of molten metal circuit material on the substrate is controlled by the porous metal interlayer, which can itself be patterned, such as having a defined circuit pattern. Thick-film silver or other metal circuits can be custom designed in complicated shapes for high temperature/high power applications. The materials designated for the circuit design allows for a low-cost method of generating silver circuits other metal circuits on a ceramic substrate.

Polymer binders, e.g., crosslinked polymer binders, have been found to be an effective film component in creating high quality transparent electrically conductive coatings or films comprising metal nanostructured networks. The metal nanowire films can be effectively patterned and the patterning can be performed with a high degree of optical similarity between the distinct patterned regions. Metal nanostructured networks are formed through the fusing of the metal nanowires to form conductive networks. Methods for patterning include, for example, using crosslinking radiation to pattern crosslinking of the polymer binder. The application of a fusing solution to the patterned film can result in low resistance areas and electrically resistive areas. After fusing, the network can provide desirable low sheet resistances while maintaining good optical transparency and low haze. A polymer overcoat can further stabilize conductive films and provide desirable optical effects. The patterned films can be useful in devices, such as touch sensors.

In a method for manufacturing a display panel according to an embodiment, a first anisotropic conductive layer is formed by ejecting a first anisotropic conductive layer forming material in order to bond the circuit board to the display panel, a reinforced curing layer is formed by ejecting a reinforced curing layer forming material onto a side surface of the first anisotropic conductive layer, a second anisotropic conductive layer is formed by ejecting a second anisotropic conductive layer forming material to an inner side of the second anisotropic conductive layer and the reinforced curing layer in order to bond the display drive integrated circuit, and a pixel is formed by ejecting a material for pixel printing to an inner side of the second anisotropic conductive layer for fixing the display drive integrated circuit.