A device includes a light source and a light guide. The light source is configured to emit photoresist-curative electromagnetic radiation. The light guide is arranged to receive the photoresist-curative electromagnetic radiation from the light source and to guide the received radiation by total internal reflection, the light guide including a pattern of emission points on at least one surface of the light guide, the emission points emitting the photoresist-curative electromagnetic radiation out of the light guide by frustration of total internal reflection caused by the emission points.

In one embodiment of the disclosure, it is proposed a photolithography device for generating structure on a photoresist substrate, the photolithography device comprising a light illumination unit and a photomask. The photomask is remarkable in that it comprises at least one layer of dielectric material and a medium having a refractive index lower than that of said dielectric material, wherein a surface of said at least one layer of dielectric material has at least one abrupt change of level forming a step, and wherein at least a base and lateral part of said surface, with respect to said step and a propagation direction of an electromagnetic wave from said light illumination unit, is in contact with said medium.

A method for printing a desired periodic pattern into a photosensitive layer on a substrate includes providing a mask bearing a periodic pattern whose period is a multiple of that of the desired pattern. The substrate is disposed in proximity to the mask, at least one beam is provided for illuminating the mask pattern to generate a transmitted light-field described by a Talbot distance. The layer is exposed to time-integrated intensity distributions in a number of sub-exposures by illuminating the mask pattern with the at least one beam while changing the separation between substrate and mask by at least a certain fraction of, but less than, the Talbot distance. The illumination or the substrate is configured relative to the mask for the different sub-exposures so that the layer is exposed to the same time-integrated intensity distributions that are mutually laterally offset by a certain distance and in a certain direction.

A method for manufacturing a display panel includes: providing a first substrate and an exposure system, wherein the exposure system includes a light source module and a first shielding unit; disposing the first shielding unit at a position between the first substrate and the light source module in the initial state; moving the first shielding unit along a first direction; moving the light source module to pass through the first shielding unit along a second direction different from the first direction, and exposing the first substrate to the light emitted by the light source module; moving the light source module along the opposite direction of the second direction; and moving the first shielding unit back to the position between the first substrate and the light source module along the opposite direction of the first direction.

The invention relates to a system (2) for producing an optical mask (35) for surface treatment, in particular surface microtexturing, said system (2) comprising: a layer of material (20) which has an outer surface (21) that is exposed to the outside environment; and a generating and depositing device for generating and depositing droplets (30) on the outer surface (21) of the layer of material (20) in which a specific arrangement (31), forming the optical mask (35) on the outer surface (21) of the layer of material (20). The invention also relates to a treatment plant comprising a system (2) of said type. The invention further relates to a method for producing a mask as well as to a method for surface treatment.

The invention relates to a system (2) for producing an optical mask (35) for surface microtexturing, said system (2) comprising: a substrate (10) having a surface (11) that is to be textured; a layer of material (20) which covers the surface (11) of the substrate (10) and has an outer surface (21) that is exposed to the outside environment; and a generating and depositing device for generating and depositing droplets (30) on the outer surface (21) of the layer of material (20), in a specific arrangement (31) under condensation, forming the optical mask (35) on the outer surface (21) of the layer of material (20). The invention also relates to a treatment plant comprising a system (2) of said type. The invention further relates to a method for producing a mask as well as to a surface microtexturing method.

An imprinting system and method. An illumination system for imprinting, during a first period of time, that illuminates a first portion of boundary region that surrounds a pattern region with a thickening dosage of light that is within a first dose range, such that the fluid in the first portion of the boundary region does not solidify but does increase a viscosity of the fluid. The illumination system, during a second period of time, illuminates the pattern region with a curing dosage of light that is within a second dose range higher than the first dose range. Prior to illumination, the imprinting includes dispensing droplets and holding a template with a template chuck such that the template contact the droplets and the droplets merge and form a fluid front that spreads through the pattern region and towards the boundary region.

Micro- and nano-patterns in imprint layers formed on a substrate and lithographic methods for forming such layers. The layers include a plurality of structures, and a residual layer having a residual layer thickness (RLT) that extends from the surface of the substrate to a base of the structures, where the RLT varies across the surface of the substrate according to a predefined pattern.

The present application discloses an ultraviolet (UV) mask device and a method for using the UV mask device. The UV mask device includes: a platform, configured for carrying a substrate thereon; a mask substrate, configured above the platform for fixing a mask corresponding to the substrate on the platform; and a light source array, configured above the mask substrate by a first distance and including a plurality of UV light-emitting diodes (UV LEDs) emitting light having a first single central wavelength.

An exposure apparatus includes a carrying device and a UV light generation device that irradiate a transparent substrate positioned on the carrying device. The carrying device includes a base, a linear electric machine, an exposure table, and a pneumatic lift device that is arranged between the exposure table and the base and supports the exposure table on the base. A stator of the linear electric machine is fixed to the base, and a rotor of the linear electric machine is fixedly coupled to the exposure table. The linear electric machine drives the exposure table to move relative to the base. A method for exposure of a transparent substrate is also provided. The linear electric machine only needs to drive the movement of the exposure table thereby helping increase exposure speed and exposure accuracy. The pneumatic lift device provides an additional function of cushioning.