A device (100) includes a light source (130) and a light guide (110). The light source (130) is configured to emit photoresist-curative electromagnetic radiation. The light guide (110) is arranged to receive the photoresist-curative electromagnetic radiation from the light source (130) and to guide the received radiation by total internal reflection, the light guide (110) including a pattern of emission points (210) on at least one surface of the light guide (110), the emission points (210) emitting the photoresist-curative electromagnetic radiation out of the light guide (110) by frustration of total internal reflection caused by the emission points (210).

An imprint lithography apparatus having a first frame to be mounted on a floor, a second frame mounted on the first frame via a kinematic coupling, an alignment sensor mounted on the second frame, to align an imprint lithography template arrangement with a target portion of a substrate, and a position sensor to measure a position of the imprint lithography template arrangement and/or a substrate stage relative to the second frame.

The present disclosure provides a secondary imaging optical lithography method and apparatus. The method includes: contacting a lithography mask plate with a flexible transparent transfer substrate closely, the flexible transparent transfer substrate comprising a first near-field imaging structure having a photosensitive layer; irradiating the photosensitive layer through the lithography mask plate with a first light source, so as to transfer a pattern of the lithography mask plate to the photosensitive layer; coating a device substrate for fabricating devices with a photoresist; contacting the flexible transparent transfer substrate with the photoresist-coated device substrate closely; irradiating the device substrate through the flexible transparent transfer substrate with a second light source, so as to transfer a pattern of the photosensitive layer to the photoresist of the device substrate; and developing the device substrate comprising an exposed photoresist, so as to obtain a device pattern conforming to the pattern of the lithography mask plate.

Embodiments disclosed herein include a lithographic patterning system and methods of using such a system to form a microelectronic device. The lithographic patterning system includes an actinic radiation source, a stage having a surface for supporting a substrate with a resist layer, and a prism with a first surface over the stage, where the first surface has a masked layer and is substantially parallel to the surface of the stage. The prism may have a second surface that is substantially parallel to the first surface. The first and second surfaces are flat surfaces. The prism is a monolithic prism-mask, where an optical path passes through the system and exits the first surface of the prism through the mask layer. The system may include a layer disposed between the mask and resist layers. The mask layer of the prism may pattern the resist layer without an isolated mask layer.

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 lithography method to pattern a first semiconductor wafer is disclosed. An optical mask is positioned over the first semiconductor wafer. A first region of the first semiconductor wafer is patterned by directing light from a light source through transparent regions of the optical mask. A second region of the first semiconductor wafer is patterned by directing energy from an energy source to the second region, wherein the patterning of the second region comprises direct-beam writing.

Provided is a multifunctional lithography device, including: a vacuum substrate-carrying stage configured to place a substrate and adsorb the substrate on the vacuum substrate-carrying stage by controlling an airflow, so as to control a gap between the substrate and the mask plate; a mask frame arranged above the vacuum substrate-carrying stage and configured to fix the mask plate; a substrate-carrying stage motion system arranged below the vacuum substrate-carrying stage and configured to adjust a position of the vacuum substrate-carrying stage, so that a distance between the substrate and the mask plate satisfies a preset condition; an ultraviolet light source system arranged above the mask plate and configured to generate an ultraviolet light for lithography; and a three-axis alignment optical path system configured to align the ultraviolet light with the mask plate.

An imprint lithography apparatus having a first frame to be mounted on a floor, a second frame mounted on the first frame via a kinematic coupling, an alignment sensor mounted on the second frame, to align an imprint lithography template arrangement with a target portion of a substrate, and a position sensor to measure a position of the imprint lithography template arrangement and/or a substrate stage relative to the second frame.

Described is a telecentric illuminator that can be used, for example, in a mask aligner system for semiconductor wafer processing or as part of a solar simulator system for characterization of solar cells. The telecentric illuminator includes a tapered optic, a lens group having a plurality of lenses and an aperture stop, and a hybrid Fresnel lens. The Fresnel lens is disposed at a position along the optical axis of the telecentric illuminator to generate a telecentric image of the aperture stop at an illumination plane. The Fresnel lens may have a curved central portion and the aperture stop may be apodized to achieve desired illumination characteristics and improve the resolution of a mask aligner system.

Provided is a method of fabricating a micro-nano structure, including: forming a reflective layer and a fluid polymer layer sequentially on a surface of a substrate; pressurizing the substrate and a mask having a micro-nano pattern to attach to each other, squeezing the fluid polymer layer into a light-transmission area of the mask, and curing the fluid polymer layer; and exposing, wherein a fluid polymer in the light-transmission area is configured to sense light under a combined effect of a transmitted light and a light reflected by the reflective layer, such that a micro-nano structure is obtained. The method solves the problem of limited diffraction, improves the processing resolution by reducing the transmission loss of evanescent waves through reflective light field enhancement, and reduces the difficulty and cost of mask processing and pattern defects by using shallow pressurizing in combination with exposure.