An exposure apparatus may include a laser light source capable of varying a wavelength of a laser beam that is emitted from the laser light source, a mask on which a pattern is formed, the pattern being configured to generate diffracted light by being irradiated with the laser beam, and a controller configured to control, in accordance with a distance between the mask and a substrate, the wavelength of the laser beam that is emitted from the laser light source, wherein the mask is irradiated with the laser beam emitted from the laser light source to perform proximity exposure on a surface of the substrate.

The present application relates to an apparatus for processing a photolithographic mask, said apparatus comprising: (a) at least one time-varying particle beam, which is embodied for a local deposition reaction and/or a local etching reaction on the photolithographic mask; (b) at least one first means for providing at least one precursor gas, wherein the precursor gas is embodied to interact with the particle beam during the local deposition reaction and/or the local etching reaction; and (c) at least one second means, which reduces a mean angle of incidence (φ) between the time-varying particle beam and a surface of the photolithographic mask.

A device manufacturing method includes conditioning a beam of radiation using an illumination system. The conditioning includes controlling an array of individually controllable elements and associated optical components of the illumination system to convert the radiation beam into a desired illumination mode, the controlling including allocating different individually controllable elements to different parts of the illumination mode in accordance with an allocation scheme, the allocation scheme selected to provide a desired modification of one or more properties of the illumination mode, the radiation beam or both. The method also includes patterning the radiation beam having the desired illumination mode with a pattern in its cross-section to form a patterned beam of radiation, and projecting the patterned radiation beam onto a target portion of a substrate.

A lithographic apparatus includes an alignment sensor including a self-referencing interferometer for reading the position of an alignment target comprising a periodic structure. An illumination optical system for focusing radiation into a spot on said structure. An asymmetry detection optical system receives a share of positive and negative orders of radiation diffracted by the periodic structure, and forms first and second images of said spot on first and second detectors respectively, wherein said negative order radiation is used to form the first image and said positive order radiation is used to form the second image. A processor for processing together signals from said first and second detectors representing intensities of said positive and negative orders to produce a measurement of asymmetry in the periodic structure. The asymmetry measurement can be used to improve accuracy of the position read by the alignment sensor.

Parameters of a structure (900) are measured by reconstruction from observed diffracted radiation. The method includes the steps: (a) defining a structure model to represent the structure in a two- or three-dimensional model space; (b) using the structure model to simulate interaction of radiation with the structure; and (c) repeating step (b) while varying parameters of the structure model. The structure model is divided into a series of slices (a-f) along at least a first dimension (Z) of the model space. By the division into slices, a sloping face (904, 906) of at least one sub-structure is approximated by a series of steps (904′, 906′) along at least a second dimension of the model space (X). The number of slices may vary dynamically as the parameters vary. The number of steps approximating said sloping face is maintained constant. Additional cuts (1302, 1304) are introduced, without introducing corresponding steps.

A catadioptric projection objective has a first objective part, defining a first part of the optical axis and imaging an object field to form a first real intermediate image. It also has a second, catadioptric objective part forming a second real intermediate image using the radiation from the first objective part. The second objective part has a concave mirror and defines a second part of the optical axis. A third objective part images the second real intermediate image into the image plane and defines a third part of the optical axis. Folding mirrors deflect the radiation from the object plane towards the concave mirror; and deflect the radiation from the concave mirror towards the image plane. The first part of the optical axis defined by the first objective part is laterally offset from and aligned parallel with the third part of the optical axis.

A patterning device, for use in forming a marker on a substrate by optical projection, the patterning device including a marker pattern having a density profile that is periodic with a fundamental spatial frequency corresponding to a desired periodicity of the marker to be formed. The density profile is modulated (such as sinusoidally) so as to suppress one or more harmonics of the fundamental frequency, relative to a simple binary profile having the fundamental frequency.

A mask (M) for EUV lithography includes: a substrate (7), a first surface region (A.sub.1) formed by a surface (8a) of a multilayer coating (8) embodied to reflect EUV radiation (27), said surface (8a) facing away from the substrate (7), and a second surface region (A.sub.2) formed by a surface (18a) of a further coating (18) embodied to reflect DUV radiation (28) and to suppress the reflection of EUV radiation (27), said surface (18a) facing away from the substrate (7). The further coating is a multilayer coating (18). Also disclosed are an EUV lithography apparatus that includes such a mask (M) and a method for determining a contrast proportion caused by DUV radiation when imaging a mask (M) onto a light-sensitive layer.

A data tuning software application platform relating to the ability to apply maskless lithography patterns to a substrate in a manufacturing process is disclosed in which the application processes graphical objects and configures the graphical objects for partition into a plurality of trapezoids. The trapezoids may be selectively merged in order to minimize the trapezoid count while limiting the loss of edge fidelity.

In one aspect, the invention relates to methods to prepare markings on diamond surfaces which are encapsulated by diamond, and the marked diamonds prepared by the disclosed methods. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present invention.