Provided are: a production method for a patterned phosphorescent body capable of producing a patterned phosphorescent body with excellent light emission (phosphorescent) performance through simple and easy production processes; a patterned phosphorescent body, and an evacuation guide sign. A mixture obtained by mixing at least a phosphorescent material and a glass material is filled in a mold and the mixture is press-molded so as to provide a planar part (10), thereby to create a molded body. The molded body is baked and slowly cooled, and then transfer paper of a water transfer type is attached to a surface of the planar part (10) of the baked molded body (4) and re-baking is performed at a temperature lower than a baking temperature of the molded body to impress a pattern (11) on the transfer paper.

A method enables a user to apply their own artistic input to a temporary tattoo design (TTD). The TTD is pre-printed on a substrate sheet which includes a synthetic oil which allows for: ease of coloring as the gel pen inks glide easily across the paper; transfer onto the skin with high-quality and vivid color results; and increased longevity of the temporary tattoo. The user first colors in the TTD with gel pens specifically designed and tested for transference onto the skin. Second, an adhesive coating is applied to the colored TTD. The colored TTD is transferred to the skin by placing the colored TTD with adhesive face-down on skin, slightly moistening the substrate with water and then removing the backing sheet. The synthetic oil added to the tattoo transfer sheet enables the colored temporary tattoo to remain on the skin for five to ten days.

In a method for printing a metal-tone printed matter, a metallic ink which includes metal particles dispersed in a solvent is applied onto a smooth printing surface of a printing medium to provide a metallic ink layer containing a metal layer having the metal particles accumulated on a printing surface side closer to the smooth printing surface in the metallic ink layer. The printing medium is reversed to transfer the metallic ink layer onto a material to be transferred while making a smooth surface of the metal layer as a display surface.

[Problem] To provide a film that has excellent water solubility which changes little over time even when the film touches a chemical, a package and a liquid transfer printing film each using the film and a liquid transfer printing method using the liquid transfer printing film. [Means for Resolution] A film containing a hydroxymethyl group-containing vinyl alcohol-based polymer containing a vinyl alcohol unit and a unit structure represented by the following formula (1), a package and a liquid transfer printing film each using the film and a liquid transfer printing method using the liquid transfer printing film. ##STR00001##

Disclosed are an activation method and a liquid pressure transfer technique, where a transfer film is supplied to the surface of a transfer liquid and then is activated, capable of continuously performing a precise transfer. In forming an appropriate transfer pattern on the surface of an object by pressing the object from the upper side of a transfer tank, in the transfer tank, a pre-activation guide mechanism that holds both sides of the film, which is supplied with the center position matching the center of the transfer tank, at horizontally equivalent positions of the transfer tank and guides the film to an activation area is disposed. Accordingly, the film is urged to swell up in the thickness direction, and, in the activation area, the film is coated with an activating agent in a state in which the guide action of the film using the pre-activation guide mechanism is cancelled.

Disclosed are an activation method and a liquid pressure transfer technique, where a transfer film is supplied to the surface of a transfer liquid and then is activated, capable of continuously performing a precise transfer. In forming an appropriate transfer pattern on the surface of an object by pressing the object from the upper side of a transfer tank, in the transfer tank, a pre-activation guide mechanism that holds both sides of the film, which is supplied with the center position matching the center of the transfer tank, at horizontally equivalent positions of the transfer tank and guides the film to an activation area is disposed. Accordingly, the film is urged to swell up in the thickness direction, and, in the activation area, the film is coated with an activating agent in a state in which the guide action of the film using the pre-activation guide mechanism is cancelled.

The capillary transfer technology presented here represents a powerful approach to transfer soft films from surface of liquid onto a solid substrate in a fast and defect-free manner. The fundamental theoretical model and transfer criteria validated with comprehensive experiments and finite element analyses, for the first time provides a quantitative guide and optimization for the choice of material systems, operating conditions and environments for scalable on-demand transfers with high yield. The intrinsically moderate capillary transfer force and externally selectable transfer direction offer robust capabilities for achieving deterministic assembly and surface properties of structures with complex layouts and patterns for potentially broad applications in the fabrication of flexible/stretchable electronics, surface wetting structures and optical devices. Integration of this technology with other advanced manufacturing technologies associated with material self-assembly, growth and layout alignment represents promising future topics and would help create emerging new manufacturing technologies that leverage unique fluidity of liquid environments.

An electrode catalyst ink composition which includes metal oxide-based electrode catalyst particles, an electrolyte, and a mixed liquid medium, wherein the mixed liquid medium contains 40 to 85% by mass of water; 5 to 30% by mass of an aqueous solvent (A) that has an evaporation rate of 2.0 or lower when the evaporation rate of water at 25 C. is 1, and a solubility parameter (SP value) of not less than 9; and 10 to 30% by mass of a monoalcohol (B) that has an evaporation rate of higher than 2.0 when the evaporation rate of water at 25 C. is 1, and not more than 3 carbon atoms, provided that the total amount of the mixed liquid medium is 100% by mass.

A hydraulic transfer film includes: a water-soluble substrate, a pattern-forming layer formed on the water-soluble substrate and having a water-soluble region and an oil-soluble region, an oil-soluble pattern layer formed on the pattern-forming layer, an oil-soluble base layer formed on the oil-soluble pattern layer, and an activating layer including a curable activating agent that permeates into the oil-soluble region, the oil-soluble pattern layer, and the oil-soluble base layer such that the oil-soluble region, the oil-soluble pattern layer, and the oil-soluble base layer are partly soluble in the curable activating agent. A method of forming the hydraulic transfer film and a pattern film are also disclosed.

A hydraulic transfer film includes: a water-soluble substrate, a pattern-forming layer formed on the water-soluble substrate and having a water-soluble region and an oil-soluble region, an oil-soluble pattern layer formed on the pattern-forming layer, an oil-soluble base layer formed on the oil-soluble pattern layer, and an activating layer including a curable activating agent that permeates into the oil-soluble region, the oil-soluble pattern layer, and the oil-soluble base layer such that the oil-soluble region, the oil-soluble pattern layer, and the oil-soluble base layer are partly soluble in the curable activating agent. A method of forming the hydraulic transfer film and a pattern film are also disclosed.