The invention relates to a method for producing a three-dimensional object in an optically reactive starting material, comprising: providing an optically reactive starting material (4) in a working volume (5), wherein the optically reactive starting material (4) contains active molecules of a dual-color photoinitiator; and optically processing the starting material (4) to produce a three-dimensional object by radiating with light of a first wavelength and light of a second wavelength that is different from the first wavelength. The optical processing comprises the following: a) radiating the light of the first wavelength through an opening (20) of an entrance pupil (11) located upstream of an objective (12) and through the objective (12), wherein the objective (12) focuses the light of the first wavelength in the starting material into a focus volume in a focus of the objective (12) such that active molecules that absorb the light of the first wavelength transition into an intermediate state; b) radiating the light of the second wavelength via the entrance pupil (11) and the objective (12), wherein the objective (12) focuses the light of the second wavelength in the starting material (4) into the focus volume such that active molecules within the focus volume that are in the intermediate state and absorb the light of the second wavelength transition into a reactive state and a chemical reaction is thereby triggered in the focus volume, by means of which a material property of the starting material (4) is locally changed; and c) producing the three-dimensional object by repeating steps a) and b) for further focus volumes; wherein, during radiation, the light of the first wavelength and the light of the second wavelength are radiated, on the path to the focus volume, in a spatially non-overlapping manner at least when passing through the entrance pupil (11) and when passing through the objective (12) and in a spatially overlapping manner in the focus volume. Furthermore, a device for producing a three-dimensional object in an optically reactive starting material is provided.

A method for forming a patterned insulating layer on a conductive layer can include severing a mask disposed on the conductive layer using photochemical ablation along a perimeter of a central region of the mask. The central region of the mask can be removed to form an opening in the mask, whereby a remaining region of the mask surrounding the opening in the mask covers a corresponding surrounding region of the conductive layer. An insulating layer can be applied to the central region of the conductive layer and the remaining region of the mask. The remaining region of the mask can be removed from the conductive layer to remove an excess portion of the insulating layer disposed on the remaining region of the mask, whereby a remaining portion of the insulating layer corresponding to the opening in the mask defines the patterned insulating layer disposed on the conductive layer.

An imaging system, including a laser source and a controller, for producing a mask for a flexographic plate. The imaging data includes a base pattern comprised of spots superimposed on the image information and aligned to a grid defined by an imaging resolution of an imager. Each spot corresponding to an imaged discrete element in the base pattern is surrounded by eight spots corresponding to non-imaged discrete elements. In at least a portion of the mask corresponding to a non-solid tonal area of the plate, the controller adjusts the laser beam to a size that causes each set of four neighboring imaged discrete elements to have an unexposed or unablated area centered therebetween, wherein the unablated area resolves to a region on a surface of the plate below an uppermost level but above a non-printing level, and each of the four neighboring imaged discrete elements resolves to the uppermost level.

A color filter and a display apparatus employing the color filter are provided. The color filter includes a base substrate and a color photoresist layer disposed on the base substrate. The color photoresist layer includes a photopolymerized photosensitive composition, at least one of a pigment and a dye, and quantum dots.

The present invention provides methods for optically micropatterning hydrogels, which may be used for, e.g., regenerative medicine, synthetic or cultured foods, and in devices suitable for use in high throughput drug screening assays.

A method for processing print data defining a pattern to be printed comprises obtaining (S10) of vector print data for the pattern to be printed. The vector print data is divided (S12) into vector print data of scan strips, wherein each scan strip is associated with a scan velocity. A skew transformation of the vector print data is performed (S14) in each scan strip. The skew transformation is performed in a direction opposite to respective scan velocity and with a magnitude proportional to a magnitude of the scan velocity. A method for printing a pattern, a device for processing print data and a printing device according to the same principles are also disclosed.

Methods of fabricating an object via direct laser lithography are provided. In embodiments, such a method comprises illuminating, via an optical fiber having an end facet and a metalens directly on the end facet, a location within a photosensitive composition from which an object is to be fabricated with light, thereby inducing a multiphoton process within the photosensitive composition to generate a region of the object; and repeating the illuminating step one or more additional times at one or more additional locations to generate one or more additional regions of the object.

The present invention is directed to refractive index contrast (“RIC”) polymers and methods for producing and using the same. In one particular embodiment, RIC polymers of the invention can be used as waveguides. RIC polymers of the invention are produced from a monomeric mixture comprising a first monomer and a second monomer comprising an acid-labile protecting group, where a first polymer produced from the first monomer has a different refractive index compared to the refractive index of a second polymer produced from the second monomer. The base refractive index of RIC polymers can be tuned by controlling the amount of the first and the second monomers. Furthermore, the refractive index of the waveguide can be modulated by the amount of acid-labile protecting group removal.

Provided are an integrated super-resolution laser direct-writing device and a direct-writing method. The integrated super-resolution laser direct-writing device includes a first continuous laser, a first optical fiber coupler, a mono-mode optical fiber, a second continuous laser, a second optical fiber coupler, a first annular photonic crystal fiber, a bifurcated optical fiber, a lens group, a first dichroic mirror, an LED light source, a lens, a second dichroic mirror, an auto-focusing module, a third dichroic mirror, a third optical fiber coupler, a square-law graded index fiber, a nanometer displacement table, a second lens, a CMOS camera and a control system. According to the present invention, an original large direct-writing device based on a free optical path can achieve optical fibers of key devices and integration of systems and can be better applied to the field of laser direct-writing.

A method for manufacturing electrically conductive structures, preferably conductive pathway structures using laser beams on a non-conductive carrier (LDS method), wherein a non-conductive carrier material is provided which contains at least one inorganic metal phosphate compound and at least one stabiliser finely distributed or dissolved therein, the carrier material is irradiated in regions by laser beams generating the electrically conductive structures in the irradiated regions.