Formation of a multi-colored image in thermochromic material involves controlling operation of first, second, and third heat sources. The first heat source heats pixels of the thermochromic material to activate the pixels. The second and third heat sources are selectively controlled to heat different sets of pixels using neither, one, or both of the second and third heat sources.

Formation of a multi-colored image in thermochromic material involves controlling operation of first, second, and third heat sources. The first heat source heats pixels of the thermochromic material to activate the pixels. The second and third heat sources are selectively controlled to heat different sets of pixels using neither, one, or both of the second and third heat sources.

A laser markable composition has an improved stability towards the environment by using specific Near Infrared absorbing compounds.

A reversible recording medium according to an embodiment of the present disclosure is a reversible recording medium that includes recording layers and heat-insulating layers that are alternately stacked, in which the recording layers each include a reversible heat-sensitive color developing composition and a first light-heat converting agent. In this reversible recording medium, the recording layers are different from each other in a developing color of their respective reversible heat-sensitive color developing compositions and are different from each other in an absorption wavelength of their respective first light-heat converting agents. This reversible recording medium further includes a heat-generating layer that includes a second light-heat converting agent having an absorption wavelength that is different from the absorption wavelength of the first light-heat converting agent included in each of the recording layers.

In a thermal transfer recording sheet including a base material and a colorant layer, the colorant layer includes a yellow dye layer containing a yellow dye, a magenta dye layer containing a magenta dye, and a cyan dye layer containing a cyan dye, and the cyan dye includes a compound represented by Formula (1a) or Formula (1b): ##STR00001##
where R.sub.1 to R.sub.7 are substituents, X.sup. is an anion, and the compound of Formula (1b) has at least one anionic substituent.

To stabilize image quality of a printed image. A thermal transfer printing apparatus according to the present invention includes a thermal head and a platen roll and forms an image on printing paper by causing the thermal head to heat an ink ribbon including a plurality of consecutive ink layers, each of which includes sequential panels of a yellow layer, a magenta layer, and a cyan layer and thereby transfer ink while transporting, between the thermal head and the platen roll, the ink ribbon and the printing paper that are superimposed on each other. The thermal transfer printing apparatus includes a sensor that detects ink content of the ink layers and a controller that controls energy applied to the thermal head during image formation on a basis of a result of the detection of the sensor.

To stabilize image quality of a printed image. A thermal transfer printing apparatus according to the present invention includes a thermal head and a platen roll and forms an image on printing paper by causing the thermal head to heat an ink ribbon including a plurality of consecutive ink layers, each of which includes sequential panels of a yellow layer, a magenta layer, and a cyan layer and thereby transfer ink while transporting, between the thermal head and the platen roll, the ink ribbon and the printing paper that are superimposed on each other. The thermal transfer printing apparatus includes a sensor that detects ink content of the ink layers and a controller that controls energy applied to the thermal head during image formation on a basis of a result of the detection of the sensor.

A recording medium of an embodiment includes a base material; a first color development layer that is located on the base material and absorbs light of a given wavelength to develop color; a second color development layer that is located closer to an incident side of the light than the first color development layer, transmits visible light and the light, and develops a color by heat; and a photothermal conversion layer that is located closer to an incident side of the light than the second color development layer intended to develop a color, transmits the visible light, and absorbs the light to photo-thermally convert the light into the heat.

According to one embodiment, a recording medium is a recording medium in a card form. The recording medium includes a substrate, and a color development layer laminated on the substrate, and provided with a line for security that extends along a lamination surface of the substrate from an end face of the recording medium, such that presence or absence of the line for security is optically identifiable at the end face. It is thus provided a recording medium that can easily prevent falsification with a simple structure, and allows authenticity determination to be performed relatively easily.

An approach for forming a multi-colored image on a substrate that includes a thermochromic material capable of producing at least two different colors is disclosed. Individually selected pixels of the thermochromic material that correspond to the image are heated to predetermined temperatures. Each predetermined temperature corresponds to a predetermined color shift of the thermochromic material. While the individually selected pixels are being heated, an area that includes the individually selected pixels is flooded with an amount of UV radiation sufficient to at least partially polymerize the thermochromic material. A color of each individually selected pixel is determined by a predetermined temperature to which the pixel is heated and the amount of UV radiation to which the pixel is exposed.