Here we disclose a lithographic pattern development process for amorphous fluoropolymers. Amorphous fluoropolymers are a class of plastic materials with high chemical inertness and favorable optical properties. Exposure of surface-deposited layers of such polymer with high energy radiation leads to a change in the chemical structure of the polymer, which selectively compromises the solubility of the exposed areas in fluorinated organic solvents. Micro- and nanopatterning with a feature size down to <50 nm was achieved by dissolving and removing unexposed amorphous fluoropolymer from exposed, surface deposited films. The amorphous fluoropolymer functions thus as a negative resist.

In one embodiment, a method of fabricating a device having at least two features of differing heights comprises: depositing a resist over a substrate; determining a topography pattern for the at least two features of the device; determining an exposure pattern for the at least two features of the device; exposing a first area of the resist with a first dose of light, the first area corresponding to a first feature of the at least two features; exposing a second area of the resist with a second dose of light that is different from the first dose of light, the second area corresponding to a second feature of the at least two features; and developing the resist.

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.

A method for critical dimension control in which a substrate is received having an underlying layer and a patterned layer formed on the underlying layer, the patterned layer including radiation-sensitive material and a pattern of varying elevation with a first critical dimension. The method further includes applying an overcoat layer over the patterned layer, the overcoat layer containing a photo agent selected from a photosensitizer generator compound, a photosensitizer compound, a photoacid generator compound, a photoactive agent, an acid-containing compound, or a combination of two or more thereof. The overcoat layer is then exposed to electromagnetic radiation, wherein the dose of electromagnetic radiation applied to different regions of the substrate is varied, and then the overcoat layer and patterned layer are heated. The method further includes developing the overcoat layer and the patterned layer to alter the first critical dimension of the patterned layer to a second critical dimension.

A flow through Micro-Electromechanical Systems (MEMS) package and methods of operating a MEMS packaged using the same are provided. Generally, the package includes a cavity in which the MEMS is enclosed, an inlet through which a fluid is introduced to the cavity during operation of the MEMS and an outlet through which the fluid is removed during operation of the MEMS, wherein the package includes features that promote laminar flow of the fluid across the MEMS. The package and method are particularly useful in packaging spatial light modulators including a reflective surface and adapted to reflect and modulate a light beam incident thereon. Other embodiments are also provided.

The invention relates to a method for producing a structure in a lithographic material, wherein the structure in the lithographic material is defined by means of a writing beam of an exposure device, in that a plurality of partial structures are written sequentially, wherein for writing the partial structures a write field of the exposure device is displaced and positioned sequentially and that a partial structure is written in the write field in each case, and wherein for positioning of the write field a reference structure is detected by means of an imaging measuring device. For calibration of the write field in the respectively positioned write field, before, during or after writing a partial structure, at least one reference structure element assigned to this partial structure is produced in the lithographic material with the writing beam, wherein the reference structure element after the displacement of the write field is detected by means of the imaging measuring device for writing a further partial structure.

An exposure method is provided. The exposure method includes coating a photo-curable material on a substrate, and exposing a portion of the photo-curable material by providing a first light source through an optical fiber to form a first photo-cured material. The optical fiber includes a light output end and a cone portion that tapers toward the light output end. The photo-curable material not exposed by the first light source is removed while leaving the first photo-cured material. Exposure equipment for performing the exposure method and a 3-dimensional structure formed thereby are also described.

A light irradiating device includes a processing chamber in which a substrate is accommodated; a beam source chamber in which a beam source of an energy beam is accommodated; a partition wall configured to partition the processing chamber and the beam source chamber; multiple window members provided at the partition wall to transmit the energy beam outputted from the beam source toward the substrate within the processing chamber; and multiple gas discharge units respectively disposed around the multiple window members within the processing chamber, and configured to discharge an inert gas along surfaces of the multiple window members.

The present invention relates to a process, an apparatus and photoswitchable photoinitiators for locally polymerizing a starting material by dual color photopolymerization and a method for volumetric printing of a shaped body (xolography). In particular, photoinitiators are provided, which cause raring of photopolymerizable formulations upon irradiation with two different wavelengths and which maybe used for volumetric printing (xolocure initiators).

A system for effectively curing dry film ink throughout its thickness on circuit boards being made applies an exposure system, a circuit board, and a method for making the circuit board. The exposure system includes a plurality of mixed light sources with different wavelengths within a range of 365 nm to 440 nm, the mixed light sources can output at least three different wavelengths of light each of substantially a single wavelength and a fourth source of light able to output light of a spectrum of wavelengths, the ranges of light being between 365 nm and 440 nm.