Abstract: A multicolor image-forming material comprises: an image-receiving sheet having an image-receiving layer and a support; and at least four thermal transfer sheets each including a support, a light-to-heat converting layer and an image-forming layer, in which each of the thermal transfer sheets has a different color, wherein a multicolor image is formed by: superposing the image-forming layer in each of the at least four thermal transfer sheets on the image-receiving layer, such that the image-forming layer is opposed to the image-receiving layer; irradiating the image-forming layer with a laser beam; transferring the irradiated area of the image-forming layer onto the image-receiving layer to form an image; and transferring the image on the image-receiving layer onto an actual printing paper, and each of the at least four thermal transfer sheets has a recording area being defined by a product of a length of 515 mm or more and width of 728 mm or more, and each of the at least four thermal transfer sheets is larg

Abstract: A thermosensitive recording material having at least a thermosensitive recording layer on one surface of a support and a back coat layer on the other surface of the support, wherein the black coat layer includes multiple layers, and an outermost layer of the back coat layer furthest from the support contains polyvinyl alcohol, an inorganic stratiform compound, and an inorganic pigment. According to the thermosensitive recording material curling caused by a change in environment or by application of heat during recording can be prevented and a coefficient of friction of a back coat layer can be regulated to within a predetermined range.

Abstract: A thermal sheet transfer having on a support, an image formation layer wherein the image formation layer includes as a colorant, an organic pigment having a melting point not less than 310° C.

Abstract: There is provided a thermal transfer sheet which can surely prevent printing-derived cockling, fusing to a thermal head or the like caused by thermal head-derived thermal damage to a primer layer provided between a substrate sheet and a heat-resistant slip layer and, at the same time, can meet a demand for a reduction in thickness of the thermal transfer sheet and has a high level of suitability for high-speed printing. The thermal transfer sheet comprises: a substrate sheet; a colorant layer provided on one side of the substrate sheet; and a heat-resistant slip layer provided on the other side of the substrate sheet through a primer layer. The primer layer comprises a binder resin satisfying a G′a/G′b ratio value of not more than 100 wherein G′a represents the storage modulus of the binder resin at 80° C., Pa; and G′b represents the storage modulus of the binder resin at 140° C., Pa.

Abstract: A thermal ink ribbon has a base sheet, a thermal recording layer arranged on one side of the base sheet, and a back layer arranged on an opposite side of the base sheet. The back layer according to the present invention comprises a polyurethane resin which is obtained by reacting a low molecular weight polymer having at least one active-hydrogen-containing group at one end of the molecule, a compound having at least one active-hydrogen group and at least one hydrophilic group except a hydroxide group, with a polyisocyanate. The back layer is excellent in the adhesiveness to a base sheet, the heat resistance relative to a thermal head and slipperiness to a thermal head; and the ink ribbon with such a back layer has no problems in printed characters and figures on printing, in the migration of impurities from the back layer into an ink layer, in smeariness of a thermal head and in its maintenance.

Abstract: The present invention provides an information medium comprising a substrate having successively disposed thereon an undercoat layer and a colorant receiving layer, wherein the colorant receiving layer comprises at least fine particles, polyvinyl alcohol, a boron compound and a mordant, and the diffusion reflectance of the undercoat layer is 10% or more; and an information medium comprising a substrate having disposed thereon a colorant receiving layer, wherein the colorant receiving layer is formed by successively applying a first coating solution and a second coating solution which are different from each other.

Abstract: The invention provides a multi-color image-forming material for recording an image by using an image-receiving sheet having an image-receiving layer and at least 4 kinds of heat transfer sheets different from each other in color and comprising a support having provided thereon at least a light-to-heat conversion layer and an image-forming layer, superposing the image-forming layer of each of the thermal transfer sheet on the image-receiving layer of the image-receiving sheet, in which the image-forming layer is opposed to the image-receiving layer, and irradiating a laser light thereto to transfer the laser-irradiated area of the image-forming layer to the image-receiving layer of the image-receiving sheet, wherein the material contains a heat transfer sheet (X) having an image-forming layer containing one selected from among Pigment Red 48:1, Pigment Red 48:3, Pigment Green 7, Pigment Blue 15:6, Pigment Blue 60, Pigment Violet 23 and Pigment Orange 43, and a method for forming a multi-color image comprises u

Abstract: A process for adjusting the energy of an imaging laser for imaging of a thermally imageable element including the steps of: (a) providing an imaging unit having a non-imaging laser and an imaging laser, the non-imaging laser having a light detector which is in communication with the imaging laser, (b) contacting a receiver element with the thermally imageable element in the imaging unit, wherein the receiver element comprises a light attenuating layer having a front surface and a back surface; (c) actuating the non-imaging laser to expose the thermally imageable element and the receiver element to an amount of light energy sufficient for the light detector to detect the amount of light reflected from the thermally imageable element and light attenuating layer of the receiver element; and (d) actuating the imaging laser to focus the imaging laser in order to expose the thermally imageable element to an amount of light energy sufficient for imaging the thermally imageable element