An inkjet printable ionic conductive ink for producing a touch sensor device is provided. The inkjet printable ionic conductive ink includes a hydrophilic polymer and an ionic salt, a mixture of solvents in which the hydrophilic polymer and the ionic salt are dissolved therein to form a solution, and a surfactant to render the solution inkjet printable. A method of producing the inkjet printable ionic conductive ink is also provided. The method includes dissolving a hydrophilic polymer and an ionic salt in a mixture of solvents to form a solution, and mixing the solution with a surfactant to render the solution inkjet printable. A touch sensor panel comprising the ionic conductive ink and a method of producing the touch sensor panel are also provided.

A method for growing a transparent conductive metal layer on a substrate is disclosed. The method includes the steps of applying crystal growth ink to a surface of the substrate, wherein the crystal growth ink includes a metal ionic precursor; and exposing the substrate to plasma irradiation to cause the growing of a crystalline metal framework on the substrate, wherein the exposure is based on a set of predefined exposure parameters.

Yellow inkjet inks are disclosed. In an example, an inkjet ink composition comprises: at least one colorant comprising at least one yellow pigment; at least one solvent comprising at least one triol; water; and at least one binder. The binder comprises a polyurethane-based binder dispersion, which comprises water and a polyurethane. The polyurethane comprises: (A) a polyisocyanate, (B) a first polyol having a chain with two hydroxyl functional groups at one end of the chain and no hydroxyl groups at an opposed end of the chain, (C) a second polyol having a chain with two hydroxyl functional groups at both ends of the chain, (D) a carboxylic acid functional group with two hydroxyl functional groups, and (E) a sulfonate or sulfonic acid functional group having two amino functional groups.

Yellow inkjet inks are disclosed. In an example, an inkjet ink composition comprises: at least one colorant comprising at least one yellow pigment; at least one solvent comprising at least one triol; water; and at least one binder. The binder comprises a polyurethane-based binder dispersion, which comprises water and a polyurethane. The polyurethane comprises: (A) a polyisocyanate, (B) a first polyol having a chain with two hydroxyl functional groups at one end of the chain and no hydroxyl groups at an opposed end of the chain, (C) a second polyol having a chain with two hydroxyl functional groups at both ends of the chain, (D) a carboxylic acid functional group with two hydroxyl functional groups, and (E) a sulfonate or sulfonic acid functional group having two amino functional groups.

A process of industrial permeographic printing and textile screen-printing for both hot and cold transfer of a graphic image onto fabric applies, as a coating to a surface on one side of a polymer film, a release or separation/detachment composition of matter. The graphic image is provided using serigraphic inks, both water and solvent based, directly onto the layer of release or separation/detachment composition of matter which coats the polymer film. The inks are placed in contact with the polymeric film coated by the layer of release or separation/detachment composition of matter, said layer bearing the inks which constitute the image on the fabric, the inks being transferred to the fabric as a result of the improved release properties of said inks due to the composition of matter.

A process of industrial permeographic printing and textile screen-printing for both hot and cold transfer of a graphic image onto fabric applies, as a coating to a surface on one side of a polymer film, a release or separation/detachment composition of matter. The graphic image is provided using serigraphic inks, both water and solvent based, directly onto the layer of release or separation/detachment composition of matter which coats the polymer film. The inks are placed in contact with the polymeric film coated by the layer of release or separation/detachment composition of matter, said layer bearing the inks which constitute the image on the fabric, the inks being transferred to the fabric as a result of the improved release properties of said inks due to the composition of matter.

The present disclosure provides a high refractive index acrylic formulation embedded with sub-10 nm metal oxide nanocrystals. The formulation is ideal for high refractive index, high transparency coating for a variety of optical applications including OLED lighting.

The present disclosure provides a high refractive index acrylic formulation embedded with sub-10 nm metal oxide nanocrystals. The formulation is ideal for high refractive index, high transparency coating for a variety of optical applications including OLED lighting.

The present disclosure is drawn to material sets for 3D printing and methods of 3D printing. The material set can include a coalescent an organic-soluble near-infrared dye having a peak absorption wavelength from 800 nm to 1400 nm. The coalescent ink can also include water and an organic co-solvent. The material set can also include a particulate polymer formulated to coalesce when contacted by the coalescent ink and irradiated by a near-infrared energy having the peak absorption wavelength.

The present disclosure is drawn to material sets for 3D printing and methods of 3D printing. The material set can include a coalescent an organic-soluble near-infrared dye having a peak absorption wavelength from 800 nm to 1400 nm. The coalescent ink can also include water and an organic co-solvent. The material set can also include a particulate polymer formulated to coalesce when contacted by the coalescent ink and irradiated by a near-infrared energy having the peak absorption wavelength.