A method of recording an image on a recording medium by applying an auxiliary liquid containing a water-soluble resin and wax particles to an intermediate image formed on an intermediate transfer member, bringing the intermediate image into contact with the recording medium at a temperature higher than a melting point of the wax particles, subsequently peeling off the intermediate image from the intermediate transfer member at a temperature lower than the melting point of the wax particles and transferring the intermediate image onto the recording medium. The method can improve the efficiency of transferring the intermediate image from the intermediate transfer member onto the recording medium.

Disclosed herein are sacrificial coating compositions comprising at least one hydrophilic polymer; at least one hygroscopic agent; at least one surfactant; at least one non-reactive silicone release agent; and water. In certain embodiments, the at least one non-reactive silicone release agent is chosen from polyether modified polysiloxane and nonreactive silicone glycol copolymers. In certain embodiments, the at least one non-reactive silicone release agent may be present in an amount ranging from about 0.001% to about 2%, based on the total weight of the composition, such as from about 0.03% to about 0.06%. Also disclosed herein is a blanket material suitable for transfix printing comprising a sacrificial coating composition, as well as an indirect printing process comprising a step of applying a sacrificial coating composition to a blanket material.

A porous layer included in a transfer body for image recording by a heat transfer method has a multiple layer configuration, and porous layers are provided such that when a thickness (mm) of each porous layer from a porous layer P(1) of the plurality of porous layers on a side closest to the surface layer to a porous layer P(n) on a side closest to the substrate is set to t(n) (n≥2), and a total thickness of the transfer body is set to T (mm), Expression (1): C×T≤t(1)+ . . . +t(n) (here, C=0.4, and T≥1) is satisfied.

A transfer type ink jet recording method including an image forming step of forming an image including an aqueous liquid component and a coloring material on an image forming surface of a transfer body, the image forming surface being formed of a water-repellent porous body; a transfer step of transferring the image from the transfer body onto a recording medium; a wetting treatment step of performing a wetting treatment by applying a wetting liquid whose contact angle with respect to the image forming surface is less than 90° onto the image forming surface before the image forming step; and a liquid absorbing step of absorbing at least part of the aqueous liquid component from the image formed in the image forming step by using the porous body in at least one of a period between the image forming step and the transfer step and a period in the transfer step.

A method and system for producing reliefs on substrates by digital inkjet printing of drops of a relief material which is deposited on localized areas of the surface of a substrate to obtain a relief surface with a relief determined by the relief material deposited, a coating sheet being incorporated over the relief material deposited, which conforms to said relief surface, the coating sheet being fixed by gluing by means of a glue which is applied together or in combination with the relief material.

Methods and apparatus to selectively control ink evaporation in printhead nozzles are disclosed. An example printhead for use with a printer includes a plurality of nozzles (142) and a plurality of valves (144) positioned adjacent respective ones of the nozzles (142) to selectively control fluid flow through the respective nozzle (142).

Provided an intermediate transfer member for use in an image forming method including: (1) applying a liquid for reducing fluidity of ink onto the intermediate transfer member; (2) forming an image by applying the ink onto the intermediate transfer member on which the liquid for reducing the fluidity of the ink is applied; and (3) transferring the image onto a recording medium, the intermediate transfer member including: a base; and an elastic layer formed on the base, the elastic layer including: a stack of a first layer being an outer layer and having a plurality of protrusions formed on a surface thereof; and a second layer located below the first layer, an elastic modulus (E1) [MPa] of the first layer and an elastic modulus (E2) [MPa] of the second layer satisfying a relationship of (E1−E2)≥5 [MPa].

An apparatus for imprint lithography can include a logic element configured to generate a fluid droplet pattern of fluid droplets of a formable material to be dispensed onto a substrate. The fluid droplet pattern includes an imprint field, wherein the imprint field has a side and a drop exclusion zone along the side, and the drop exclusion zone is narrower at a first point farther from the center of a side and wider at a second point closer to the center of the side. In another aspect, a method can be carried out using the apparatus. The apparatus and method can be useful in filling an imprint field with a formable material relatively quickly without extrusion defects or other complications.

An apparatus for imprint lithography can include a logic element configured to generate a fluid droplet pattern of fluid droplets of a formable material to be dispensed onto a substrate. The fluid droplet pattern includes an imprint field, wherein the imprint field has a side and a drop exclusion zone along the side, and the drop exclusion zone is narrower at a first point farther from the center of a side and wider at a second point closer to the center of the side. In another aspect, a method can be carried out using the apparatus. The apparatus and method can be useful in filling an imprint field with a formable material relatively quickly without extrusion defects or other complications.

Aqueous inkjet compositions comprising a composite resin vehicle wherein at least one component of the composite resin vehicle is a polyurethane dispersion (PUD) preferably with a glass transition temperature (Tg) of less than 80° C., and the other component is an acrylic resin dispersion preferably with a Tg of greater than 40° C. or a metal oxide nanoparticle dispersion such as colloidal silica with a particle size of less than 100 nm.