A method of forming sub-resolution features that includes: exposing a photoresist layer formed over a substrate to a first ultraviolet light (UV) radiation having a first wavelength of 365 nm or longer through a mask configured to form features at a first critical dimension, the photoresist layer including first portions exposed to the first UV radiation and second portions unexposed to the first UV radiation after exposing with the first UV radiation; exposing the first portions and the second portions to a second UV radiation; and developing the photoresist layer after exposing the photoresist layer to the second UV radiation to form the sub-resolution features having a second critical dimension less than the first critical dimension.

A device manufacturing method including: performing a first exposure on a substrate using a first lithographic apparatus to form a first patterned layer including first features; processing the substrate to transfer the first features into the substrate; and performing a second exposure on the substrate using a second lithographic apparatus to form a second patterned layer including second features, wherein: the first lithographic apparatus has first and second control inputs effective to control first and second parameters of the first features at least partly independently; the second lithographic apparatus has a third control input effective to control the first and second parameters of the second features together; and the first exposure is performed with the first and/or second control input set to pre-bias the first and/or second parameter.

The present disclosure relates a lithographic substrate marking tool. The tool includes a first electromagnetic radiation source disposed within a housing and configured to generate a first type of electromagnetic radiation. A radiation guide is configured to provide the first type of electromagnetic radiation to a photosensitive material over a substrate. A second electromagnetic radiation source is disposed within the housing and is configured to generate a second type of electromagnetic radiation that is provided to the photosensitive material.

The mark position is measured with a multi-beam with high accuracy. A multi charged particle beam writing method includes forming a multi-beam (30a-30e) in which charged particle beams are arranged with a predetermined pitch, irradiating a mark (M) with beams in an on-beam region while shifting irradiation positions of the charged particle beams by sequentially changing the on-beam region in which beams in a partial region of the multi-beam (30a-30e) are set to ON, the mark (M) being provided at a predetermined position and having a width greater than the predetermined pitch, detecting a reflected charged particle signal from the mark (M), and calculating a position of the mark (M), and adjusting the irradiation positions of the multi-beam based on the calculated position of the mark (M), and writing a pattern.

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.

A semiconductor processing system includes a first photolithography system and a second photolithography system. The semiconductor processing system includes a layout database that stores a plurality of layouts indicating features to be formed in a wafer. The semiconductor processing system includes a layout analyzer that analyzes the layouts and selects either the first photolithography system or the second photolithography system based on dimensions of features in the layouts.

A method for determining lithographic matching performance includes obtaining first monitoring data from recurrent monitoring for stability control for an available EUV scanner. For a DUV scanner, second monitoring data is similarly obtained from recurrent monitoring for stability control. The EUV first monitoring data are in a first layout. The DUV second monitoring data are in a second layout. A cross-platform overlay matching performance between the first lithographic apparatus and the second lithographic apparatus is determined based on the first monitoring data and the second monitoring data. This is done by reconstructing the first and/or second monitoring data into a common layout to allow comparison of the first and second monitoring data.

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 overlay measurement method for accurately measuring and correcting an overlay in an environment in which a deep ultraviolet (DUV) apparatus and an extreme ultraviolet (EUV) apparatus are used together, a semiconductor device manufacturing method using the overlay measurement method, and an overlay measurement apparatus are provided. The overlay measurement method includes performing an absolute measurement of a position of an overlay mark of at least one of a plurality of layers, based on a fixed position, wherein an exposure process is performed on a first layer of the plurality of layers by using the DUV apparatus, and an exposure process is performed on an nth layer of the plurality of layers, which is an uppermost layer of the plurality of layers, by using the EUV apparatus.

A method forms a pattern of metallic nanofeatures that generates by plasmonic resonance a desired image having a distribution of colors. The method includes providing a substrate having a layer of photosensitive material, exposing the layer to a high-resolution periodic pattern of dose distribution, and determining a low-resolution pattern of dose distribution such that the sum of the low-resolution pattern and the high-resolution periodic pattern of dose distribution is suitable for forming the pattern of metallic nanofeatures. The lateral dimensions of the metallic nano-features have a spatial variation across the pattern that corresponds to the distribution of colors in the desired image. The layer of photosensitive material is exposed to the low-resolution pattern of dose distribution. The layer of photosensitive material is developed to produce a pattern of nanostructures in the developed photosensitive material. The pattern of nanostructures is processed so that the pattern of metallic nanofeatures is formed.