Printing process in which a substrate to be printed is disposed opposite an ink carrier having an ink layer, the ink layer being irradiated regionally by a laser beam, said layer accelerating by absorption of the laser beam in the substrate direction, wherein for laser absorption the ink layer is admixed with reflective particles and as soluble polymer having a weight average (Mw) molecular weight of greater than 250 000 g/mol.

Provided is a light-absorbing material flying apparatus including: a light-absorbing material that absorbs light; and a light-absorbing material flying section configured to irradiate the light-absorbing material with an optical vortex laser beam corresponding to a light absorption wavelength of the light-absorbing material to fly the light-absorbing material by an energy of the optical vortex laser beam in a direction in which the optical vortex laser beam is emitted to attach the light-absorbing material on an attachment target.

A thermal transfer film for preparing Organic Light Emitting Diode (OLED) and a method for preparing the same are revealed. A heat resistant layer and a functional layer are disposed on a base layer respectively by coating. And a transfer layer is arranged over the functional layer. The transfer layer is heated by a thermal print head (TPH) and then is transferred onto a substrate. During the conventional vacuum evaporation used for preparing the OLED, material that reaches the substrate is less than 50%. Compared with the vacuum evaporation, the thermal transfer film and the method for preparing the same solve the problem of low material efficiency.

A method for applying a patterned structure on a surface, comprising providing a donor substrate (1) comprising donor material (1a) between a light source (3) and a receiving surface (5), providing by means of the light source (3) a light pulse (3a) directed to the donor substrate (1), the light pulse (3a) being configured to cause the donor material (1a) to be transferred from the donor substrate (1) onto the receiving surface (5), wherein the donor substrate (1) comprises a pattern (2) of donor material (1a) on discrete portions (2a) of the donor substrate (1). The pattern (2) on the donor substrate (1) is transferred so as to form a pattern (4) of donor material (1a) on the receiving surface (5).

Printing process in which a substrate to be printed is disposed opposite an ink carrier having an ink layer, the ink layer being irradiated regionally by a laser beam, said layer accelerating by absorption of the laser beam in the substrate direction, wherein for laser absorption the ink layer comprises reflective particles, a solvent, and a soluble polymer, wherein the reflective particles have an aspect ratio>25, the aspect ratio being defined as the average particle size/average particle thickness.

The invention relates to a method for transferring colored markings or labels onto plastic surfaces by means of a laser beam, to a transfer medium for carrying out said method and to articles, the plastic surfaces of which are laser-marked or laser-labeled by way of such a method.

A system for performing substrateless and/or local donor Laser Induced Forward Transfer (LIFT), comprising a reservoir comprising at least one opening and an energy source configured to deliver energy to a donor material within said reservoir, characterized by at least one of: said reservoir is embedded into a medical device; said reservoir is in fluid connection with a medical device; said reservoir is incorporated into a medical device; said reservoir contains at least one biologically active substance; and, said reservoir is in fluid connection with at least one source of at least one biologically active substance. This system enables deposition of material by LIFT without any need for a donor substrate. Methods of substrateless and local donor LIFT, in particular for medical and biological applications, are also disclosed.

A transfer printing process that exploits the mismatch in mechanical or thermo-mechanical response at the interface of a printable micro- or nano-device and a transfer stamp to drive the release of the device from the stamp and its non-contact transfer to a receiving substrate are provided. The resulting facile, pick-and-place process is demonstrated with the assembling of 3-D microdevices and the printing of GAN light-emitting diodes onto silicon and glass substrates. High speed photography is used to provide experimental evidence of thermo-mechanically driven release.

A method for forming an image, the method including forming an image by irradiating an ink that absorbs light with a laser beam that has a wavelength corresponding to a light absorption wavelength of the ink to fly the ink by an energy of the laser beam in a direction in which the laser beam is emitted, to attach the ink on an attachment target.

A system for performing substrateless and/or local donor Laser Induced Forward Transfer (LIFT), comprising a reservoir comprising at least one opening and an energy source configured to deliver energy to a donor material within said reservoir, characterized by at least one of: said reservoir is embedded into a medical device; said reservoir is in fluid connection with a medical device; said reservoir is incorporated into a medical device; said reservoir contains at least one biologically active substance; and, said reservoir is in fluid connection with at least one source of at least one biologically active substance. This system enables deposition of material by LIFT without any need for a donor substrate. Methods of substrateless and local donor LIFT, in particular for medical and biological applications, are also disclosed.