A method for producing a three-dimensional object comprises the following operations: introducing a composition into a polymerization vessel; and polymerizing the composition by multiphoton polymerization, by means of a light source, in predetermined spots, in order to produce the three-dimensional object, the composition comprising at least one monomer, at least one filler and at least one photoinitiator, the composition having a transmittance per unit of length to the emission wavelengths of the light source, which is preferably higher than 75% and the at least one filler comprises nanoparticles.

Systems and methods are described herein for electron-beam lithography. In some aspects, a photo electron emitter and channel array assembly (PEECAA) may include a photo-electron emitting cathode having a uniform planar surface and an array of beam channels proximate to the cathode. In some cases, at least one of the cathode or the array of beam channels is removable from the PEECAA. The array of beam channels may include a grid of apertures, a plurality of beam channels, and a shared lens array including a plurality of lenses proximate to an exit of the plurality of beam channels. Individual apertures of the grid of apertures align with individual beam channels to allow electrons from the cathode to pass through the array of beam channels and the shared lens array to form a pixelated pattern, such that, upon exposure to the target, the pixelated pattern is permanently formed on the target.

The technology disclosed relates to high utilization of donor material in a writing process using Laser-Induced Forward Transfer. Specifically, the technology relates to reusing, or recycling, unused donor material by recoating target substrates with donor material after a writing process is performed with the target substrate. Further, the technology relates to target substrates including a pattern of discrete separated dots to be individually ejected from the target substrate using LIFT.

A method of assembling a three-dimensional printing system includes providing a plurality of components, providing a plurality of spacer rings, and measurement, analysis and assembly steps. The components include a light engine, an adaptive support apparatus, a plurality of elongate struts, and a support plate. The measurement, analysis and assembly steps include (1) measuring a scale factor for the light engine, (2) determining a selection of one or more of the spacer rings based upon the measured scale factor, and (3) assembling the components with the determined selection of one or more spacer rings.

A scaffold includes struts that intersect at nodes. In some instances, a cross section of the cores has at least one dimension less than 100 microns. The core can be a solid, liquid or a gas. In some instances, one or more shell layers are positioned on the core.

In an aspect, a method for making a metal-containing material comprises steps of: forming a metal-containing hydrogel from an aqueous precursor mixture using a photopolymerization; wherein the aqueous precursor mixture comprises water, one or more aqueous photosensitive binders, and one or more aqueous metal salts; and thermally treating the metal-containing hydrogel to form the metal-containing material; wherein the metal-containing hydrogel is exposed to a thermal-treatment atmosphere during the step of thermally treating; wherein a composition of the metal-containing material is at least partially determined by a composition of the thermal-treatment atmosphere during the thermally treating step.

Embodiments disclosed herein include a lithographic patterning system and methods of using such a system to form a microelectronic device. In an embodiment, the lithographic patterning system includes an actinic radiation source, a stage where a major surface of the stage is for supporting a substrate with a resist layer, and a first prism over the stage, where the first prism comprises a first face that is substantially parallel to the major surface of the stage. In an embodiment, the lithographic patterning system further comprises a second prism, where the second prism comprises a first surface that is substantially parallel to a second surface of the first prism, and where a second surface of the second prism has a reflective coating.

A scaffold includes struts that intersect at nodes. In some instances, a cross section of the cores has at least one dimension less than 100 microns. The core can be a solid, liquid or a gas. In some instances, one or more shell layers are positioned on the core.

A method of producing a test body for diffusion tensor imaging, which comprises a plurality of channels in a structuring material, the channels preferably having a maximum cross-section of 625 ?m.sup.2, wherein a virtual model of the test body is created and the virtual model is fed to a structuring device which produces the test body by means of a 3D printing-based, in particular lithography-based, structuring process, the structuring process being designed as a multiphoton lithography process, in particular as a multiphoton absorption process, in which the structuring material containing a photosensitizer or photoinitiator is irradiated in a location-selective manner, wherein the radiation is successively focused on focal points lying within the structuring material, resulting in that in each case a volume element of the material located in the focal point is subjected to a change in state by means of a photochemical reaction as a result of multiphoton absorption.

Embodiments of the present disclosure provide improved photolithography systems and methods using a solid state emitter array. The solid state emitter array comprises solid state emitter devices arranged in rows and columns, wherein each solid state emitter device comprises two or more subpixels. Each solid state emitter device comprises one program gate which may transmit a voltage to a state storage node. The state storage node is in electrical communication with a drive gate. The drive gate is in communication with two or more solid state emitter subpixels. The arrangement of a plurality of subpixels in communication with a single drive gate allows more than one pulse to be delivered to the drive gate, resulting in illumination of more than one subpixel at each drive gate. The redundancy results in improved data efficiency.