A linerless thermal sheet arranged as a roll, includes a substrate having a first face and a second face, whereby the first face opposes the second face; an adhesive layer on at least part of the first face of the substrate; a thermosensitive layer on at least part of the second face of the substrate, the thermosensitive layer including a first portion and a second portion whereby the first portion and the second portion do not overlap; a release coating applied onto the thermosensitive layer, the release coating has a low adherence to the adhesive layer; at least one colour image is deposited on the first portion of the thermosensitive layer such that the at least one colour image is between the thermosensitive layer and the release coating, whereby the second portion of the thermosensitive paper is blank for thermally-printed information.

A linerless thermal sheet arranged as a roll, includes a substrate having a first face and a second face, whereby the first face opposes the second face; an adhesive layer on at least part of the first face of the substrate; a thermosensitive layer on at least part of the second face of the substrate, the thermosensitive layer including a first portion and a second portion whereby the first portion and the second portion do not overlap; a release coating applied onto the thermosensitive layer, the release coating has a low adherence to the adhesive layer; at least one colour image is deposited on the first portion of the thermosensitive layer such that the at least one colour image is between the thermosensitive layer and the release coating, whereby the second portion of the thermosensitive paper is blank for thermally-printed information.

A thermosensitive recording medium includes a support; a first underlayer disposed on or above the support; a second underlayer disposed on or above the first underlayer; and a thermosensitive recording layer disposed on or above the second underlayer. The second underlayer and the thermosensitive recording layer are formed by simultaneous curtain coating. Surface smoothness of a surface of the thermosensitive recording medium is 1,000 s or greater.

Provided is a thermosensitive recording medium being excellent in oil resistance among various performances required for the thermosensitive recording medium, and being further excellent in heat resistance, plasticizer resistance, and printing (recording) run-ability.

That is a thermosensitive recording medium having a thermosensitive recording layer comprising a colorless or pale colored electron donating leuco dye and an electron accepting color developing agent on a substrate, wherein the thermosensitive recording layer contains at least two kinds of urea compounds. The two kinds of urea compounds comprise the first urea compound being represented by the following general formula 1, and the second urea compound being represented by the following general formula 2.

##STR00001##

wherein R.sup.1 represents a substituted or unsubstituted alkyl group, aralkyl group or aryl group, and R.sup.2 represents a hydrogen atom or an alkyl group,

##STR00002##

wherein R.sup.4 to R.sup.8 represent a hydrogen atom, a halogen atom, a nitro group, an amino group, an alkyl group, an alkoxy group, an aryloxy group, and the like, and m represents an integer of 0 to 2.

A recording medium includes a support substrate and a recording layer provided on the support substrate. The recording layer contains a color-exhibiting compound having an electron-donating property, a color-developing agent having an electron-accepting property, and a matrix polymer. The color-developing agent contains a compound represented by a specific formula. The matrix polymer contains a polycarbonate resin.

A heat-sensitive recording material has a web-shaped substrate, having a front side and a reverse side opposite the front side, a heat-sensitive recording layer disposed to the front side of the web-shaped substrate, including at least one dye precursor and at least one (color) developer reactive with this at least one dye precursor. A front-side surface of the heat-sensitive recording material is formed dehesively with respect to layers of adhesive applied to the reverse side of the web-shaped substrate. The dehesive front-side surface includes a furnish which is disposed above the heat-sensitive recording layer and comprises at least one release agent. A diffusion layer is formed between the furnish and the heat-sensitive recording layer. A method for producing a heat-sensitive recording material of this kind, and possibilities for its use.

A heat-sensitive recording material has a web-shaped substrate, having a front side and a reverse side opposite the front side, a heat-sensitive recording layer disposed to the front side of the web-shaped substrate, including at least one dye precursor and at least one (color) developer reactive with this at least one dye precursor. A front-side surface of the heat-sensitive recording material is formed dehesively with respect to layers of adhesive applied to the reverse side of the web-shaped substrate. The dehesive front-side surface includes a furnish which is disposed above the heat-sensitive recording layer and comprises at least one release agent. A diffusion layer is formed between the furnish and the heat-sensitive recording layer. A method for producing a heat-sensitive recording material of this kind, and possibilities for its use.

A set of laminates includes an outer laminate and an inner laminate, wherein the outer laminate includes a transparent polymeric support including on a first side of the support a color laser markable layer containing an infrared dye having an absorption maximum λ.sub.max(IR-1) in the infrared region; wherein the inner laminate includes a transparent polymeric support including on, a first side of the transparent polymeric support, a color laser markable layer containing an infrared dye having an absorption maximum λ.sub.max(IR-2) in the infrared region and, on a second side of the transparent polymeric support, a color laser markable layer containing an infrared dye having an absorption maximum λ.sub.max(IR-3) in the infrared region; and the conditions a) and b) are satisfied:
λ.sub.max(IR-1)>λ.sub.max(IR-2)>λ.sub.max(IR-3); and  a)
λ.sub.max(IR-1)>1100 nm and λ.sub.max(IR-3)<1000 nm.  b)

A set of laminates includes an outer laminate and an inner laminate, wherein the outer laminate includes a transparent polymeric support including on a first side of the support a color laser markable layer containing an infrared dye having an absorption maximum λ.sub.max(IR-1) in the infrared region; wherein the inner laminate includes a transparent polymeric support including on, a first side of the transparent polymeric support, a color laser markable layer containing an infrared dye having an absorption maximum λ.sub.max(IR-2) in the infrared region and, on a second side of the transparent polymeric support, a color laser markable layer containing an infrared dye having an absorption maximum λ.sub.max(IR-3) in the infrared region; and the conditions a) and b) are satisfied:
λ.sub.max(IR-1)>λ.sub.max(IR-2)>λ.sub.max(IR-3); and  a)
λ.sub.max(IR-1)>1100 nm and λ.sub.max(IR-3)<1000 nm.  b)

A drawing method according to an embodiment of the present disclosure to be performed on a heat-sensitive recording medium including a recording layer, the recording layer containing a leuco dye and a photothermal conversion agent that absorbs infrared wavelength light, includes: performing drawing in a plurality of first regions, the plurality of first regions each extending in one direction and having gaps therebetween; and thereafter detecting recorded states of the plurality of first regions, calculating differences from the input image information, and performing drawing in a plurality of second regions at recording intensities determined on a basis of the differences, the plurality of second regions each extending in the one direction and being provided at the gaps between the plurality of first regions.