An ink composition includes: a quantum dot including one or more ligands on a surface thereof; a first monomer including one or more epoxy groups; and a second monomer including one or more oxetane groups, wherein the one or more ligands include one or more polar moieties. An electronic apparatus includes a film formed utilizing the ink composition.

The invention is directed towards a composition comprising: a near-infrared radiation absorbing compound; a colour-forming compound; and a heat transfer agent operable to facilitate heat transfer from the near-infrared radiation absorbing compound to the colour-forming compound; wherein the near-infrared radiation absorbing compound is present in an amount of 0.1-3.5 wt % of the total composition, and the heat transfer agent is present in an amount of 1-15 wt % of the total composition, and the heat transfer agent is present in the composition as solid particles. The invention further relates to substrates comprising the composition applied thereto, as well as methods of forming colour or an image on said substrates.

Optically active formulations useful as inks in extrusion-based deposition techniques and solids formed of the formulations are described. Formulations include a cellulose derivative in a chiral nematic phase and a polyethylene glycol interspersed with the cellulose derivative as stabilization to the cholesteric pitch of the chiral nematic phase. The inks can be utilized in direct ink writing processes to produce printed films or three-dimensional structures with long-lasting colors that stem from the nanostructure of the chiral nematic phase. The ink can include reactive monomers which can be polymerized to create optically active solid elastomers.

Optically active formulations useful as inks in extrusion-based deposition techniques and solids formed of the formulations are described. Formulations include a cellulose derivative in a chiral nematic phase and a polyethylene glycol interspersed with the cellulose derivative as stabilization to the cholesteric pitch of the chiral nematic phase. The inks can be utilized in direct ink writing processes to produce printed films or three-dimensional structures with long-lasting colors that stem from the nanostructure of the chiral nematic phase. The ink can include reactive monomers which can be polymerized to create optically active solid elastomers.

Provided are an aqueous fluorescent ink with which a fluorescent color image having an excellent color developability and lightfastness can be recorded, and an ink cartridge and an ink jet recording method using this aqueous fluorescent ink. The aqueous fluorescent ink contains a resin particle dyed with a fluorescent dye, and a quinacridone pigment. The fluorescent dye includes a basic dye having a xanthene skeleton. The resin particle has a cyano group-containing unit. A mass ratio of a content (% by mass) of the quinacridone pigment to a content (% by mass) of the fluorescent dye is 1.0 times or less. The ink cartridge includes an ink storage portion storing this aqueous fluorescent ink. An image is recorded onto a recording medium by the ink jet recording method comprising ejecting the aqueous fluorescent ink from an ink jet recording head.

Provided are an aqueous fluorescent ink with which a fluorescent color image having an excellent color developability and lightfastness can be recorded, and an ink cartridge and an ink jet recording method using this aqueous fluorescent ink. The aqueous fluorescent ink contains a resin particle dyed with a fluorescent dye, and a quinacridone pigment. The fluorescent dye includes a basic dye having a xanthene skeleton. The resin particle has a cyano group-containing unit. A mass ratio of a content (% by mass) of the quinacridone pigment to a content (% by mass) of the fluorescent dye is 1.0 times or less. The ink cartridge includes an ink storage portion storing this aqueous fluorescent ink. An image is recorded onto a recording medium by the ink jet recording method comprising ejecting the aqueous fluorescent ink from an ink jet recording head.

A method for measuring the radiant exposure of energy curable inks or coatings on a printing press. The steps for measuring comprise: a) providing an ink or coating material comprising a fluorescent probe; b) transferring the ink or coating material onto a substrate using a printing process; c) exposing the ink or coating material to actinic radiation capable of initiating cure of the ink or coating material that also alters the luminescence of the probe; d) exposing the ink or coating to a first source of excitation light with wavelength and luminance capable of absorption by the fluorescent probe; and e) measuring the emitted light from the fluorescent probe by a first detector.

A method for measuring the radiant exposure of energy curable inks or coatings on a printing press. The steps for measuring comprise: a) providing an ink or coating material comprising a fluorescent probe; b) transferring the ink or coating material onto a substrate using a printing process; c) exposing the ink or coating material to actinic radiation capable of initiating cure of the ink or coating material that also alters the luminescence of the probe; d) exposing the ink or coating to a first source of excitation light with wavelength and luminance capable of absorption by the fluorescent probe; and e) measuring the emitted light from the fluorescent probe by a first detector.

Water-based formulations comprising an indicating composition dispersed in water are described. The water-based indicating compositions include an organic Bi(III) compound, a sulfur source, a carbonate salt, and strontium hydroxide. Formulations further including a resin and/or an acidic additive are also described.

Water-based formulations comprising an indicating composition dispersed in water are described. The water-based indicating compositions include an organic Bi(III) compound, a sulfur source, a carbonate salt, and strontium hydroxide. Formulations further including a resin and/or an acidic additive are also described.