A patterning method and a method for manufacturing an array substrate are provided, and the patterning method includes: forming a photolithography auxiliary film and a positive photoresist film in turn on a base substrate provided with a layer to be patterned; subjecting the photolithography auxiliary film and the positive photoresist film to a photolithography process to form a photolithography auxiliary layer pattern and a positive photoresist pattern; patterning the layer to be patterned; and UV irradiating the photolithography auxiliary layer pattern and the positive photoresist pattern and then removing the photolithography auxiliary layer pattern and the positive photoresist pattern.

A system and method for providing a radiation source. In one arrangement, the radiation source includes an optical fiber that is hollow, and has an axial direction, a gas that fills the hollow of the optical fiber, and a plurality of temperature setting devices disposed at respective positions along the axial direction of the optical fiber, wherein the temperature setting devices are configured to control the temperature of the gas to locally control the density of the gas.

A system and method for providing a radiation source. In one arrangement, the radiation source includes an optical fiber that is hollow, and has an axial direction, a gas that fills the hollow of the optical fiber, and a plurality of temperature setting devices disposed at respective positions along the axial direction of the optical fiber, wherein the temperature setting devices are configured to control the temperature of the gas to locally control the density of the gas.

Embodiments described herein provide a lithographic system having two or more lithographic tools connected to a radiation source using two or more variable attenuation units. In some embodiments, the variable attenuation unit reflects a portion of the received light beam to the lithographic tool attached thereto and transmits a remaining portion of the received light beam to the lithographic tools downstream. In some embodiments, the radiation source includes two or more laser sources to provide laser beams with an enhanced power level and which can prevent operation interruption due to laser source maintenances and repair.

A semiconductor device is provided that includes a silicon carbide substrate including a main surface at which a plurality of doped zones are formed in a junction termination extension zone of the silicon carbide substrate, the plurality of doped zones are arranged such that a lateral dopant concentration gradient is formed that decreases from a central region of the silicon carbide substrate to an outer edge region of the silicon carbide substrate.

A period from a time point when a wafer W is carried into a housing 10 to a time point when the wafer W after being exposed is completely ready to be carried out is set as a single cycle. A time period before a next cycle is begun and after the single cycle is completed is referred to as a standby time period. When an illuminance in dummy light emission is set to be Id; an illuminance in exposure, Is; a time length of the dummy light emission, Td; and a time length of the exposure, Ts, by setting the Id to satisfy an expression of Id=(Tp/Td).Math.Iw(Ts/Td).Math.Is, an average illuminance within the single cycle is maintained constant between substrates.

A projection exposure apparatus for semiconductor lithography having a projection optical unit. The projection optical unit includes a sensor frame, a carrying frame, and a module. The module includes an optical element and actuators for positioning and orienting the optical element. The module is on the carrying frame, and the sensor frame is a reference for the positioning of the optical element. The module includes an infrastructure which includes interfaces for separating a module from the projection optical unit. A method exchanges the module of a projection optical unit of a projection exposure apparatus for semiconductor lithography, wherein the module includes an optical element, while the reference remains in the projection exposure apparatus.

Embodiments described herein provide a system, a software application, and a method of a lithography process, to write full tone portions and grey tone portions in a single pass. One embodiment includes a controller configured to provide mask pattern data to a lithography system. The controller is configured to divide a plurality of spatial light modulator pixels spatially by at least a grey tone group and a full tone group of spatial light modulator pixels. When divided by the controller, the grey tone group of spatial light modulator pixels is operable to project a first number of the multiplicity of shots to the plurality of full tone exposure polygons and the plurality of grey tone exposure polygons, and the full tone group of spatial light modulator pixels is operable to project a second number of the multiplicity of shots to the plurality of full tone exposure polygons.

An exposure device has a cylindrical peripheral wall member. The peripheral wall member forms a processing space in which a substrate is storable and has an upper opening and a lower opening. Further, a light emitter is provided in an upper portion of the peripheral wall member to close the upper opening. A lower lid member that is provided to be movable in an up-and-down direction and configured to be capable of closing and opening the lower opening is provided below the peripheral wall member. The atmosphere in the processing space is replaced with an inert gas with the substrate stored in the processing space and the lower opening closed by the lower lid member. In this state, vacuum ultraviolet rays are emitted to the substrate from the light emitter, and the substrate is exposed.

One of gamma ray lithography systems includes a gamma ray generator and a wafer stage. The gamma ray generator is configured to generate a substantially uniform gamma ray. The gamma ray generator includes a plurality of gamma ray sources and a rotational carrier. The rotational carrier is configured to hold the gamma ray sources and rotate along a rotational axis. The wafer stage is disposed below the gamma ray generator and configured to secure a wafer.