A method of manufacturing a semiconductor device includes dividing a number of dies along an x axis in a die matrix in each exposure field in an exposure field matrix delineated on the semiconductor substrate, wherein the x axis is parallel to one edge of a smallest rectangle enclosing the exposure field matrix. A number of dies is divided along a y axis in the die matrix, wherein the y axis is perpendicular to the x axis. Sequences SNx0, SNx1, SNx, SNxr, SNy0, SNy1, SNy, and SNyr are formed. p*(Nbx+1)-2 stepping operations are performed in a third direction and first sequence exposure/stepping/exposure operations and second sequence exposure/stepping/exposure operations are performed alternately between any two adjacent stepping operations as well as before a first stepping operation and after a last stepping operation. A distance of each stepping operation in order follows the sequence SNx.

A method for source mask optimization to increase scanner throughput for a patterning process is described. The method includes computing a multi-variable cost function of design variables that are representative of characteristics of the patterning process. The design variables may include (a) an illumination variable that is characteristic of an illumination system, and (b) a design layout variable that is characteristic of a design layout. The multi-variable cost function may be a function of a throughput of the patterning process. The method further includes reconfiguring the characteristics of the patterning process by adjusting the design variables until a predefined termination condition is satisfied.

A device, a computer program, a computer readable medium and a method setting respective relative laser intensities to a plurality of pixels representing a lithographic exposure. The plurality of pixels comprises at least one edge pixel arranged on an edge of an area of pixels to be exposed, and at least one neighbouring pixel. The at least one neighbouring pixel is arranged one pixel away from the at least one edge pixel in a perpendicular direction away from the edge towards the area of pixels to be exposed. The method comprises decreasing proportionally a relative laser intensity of each pixel of the plurality of pixels from a previously set respective first relative laser intensity to a respective second relative laser intensity. A laser dose translation of relative laser intensity of pixels proportionally adjusted from a previously set first laser dose translation of the first relative laser intensity to a second laser dose translation of the second relative laser intensity. The proportional adjustment is such that a respective effective exposed laser dose of each pixel is achieved by the second laser dose translation of the respective second relative laser intensity which is equal to a respective effective exposed laser dose of each pixel that would have resulted from the first laser dose translation of the respective first relative laser intensity. The respective relative laser intensity of an edge pixel of the at least one edge pixel or of a neighbouring pixel of the at least one neighbouring pixel is increased by a constant additive term from the respective second relative laser intensity to a respective third relative laser intensity.

A radiation measurement system (200) comprising an optical apparatus (205) configured to receive a radiation beam (210) and change an intensity distribution of the radiation beam to output a conditioned radiation beam (215), and a spectrometer (220) operable to receive the conditioned radiation beam and determine spectral content of the conditioned radiation beam. The radiation measurement system may form part of a lithographic apparatus.

The present disclosure provides a method for an extreme ultraviolet (EUV) lithography system that includes a radiation source having a laser device configured with a mechanism to generate an EUV radiation. The method includes collecting a laser beam profile of a laser beam from the laser device in a 3-dimensional (3D) mode; collecting an EUV energy distribution of the EUV radiation generated by the laser beam in the 3D mode; performing an analysis to the laser beam profile and the EUV energy distribution, resulting in an analysis data; and adjusting the radiation source according to the analysis data to enhance the EUV radiation.

Embodiments of the present disclosure disclose a lithography method, a lithography apparatus, and a computer storage medium. The method includes: determining an exposure intensity of a mask aligner; determining a target preset interval corresponding to the mask aligner according to the exposure intensity; determining, according to the target preset interval, at least one target wafer for which at least one exposure dose is a target exposure dose, the target preset interval has a corresponding relationship with the target exposure dose; and performing lithography process on the at least one target wafer by using the mask aligner.

In a method of forming a pattern, a photo resist layer is formed over an underlying layer, the photo resist layer is exposed to an actinic radiation carrying pattern information, the exposed photo resist layer is developed to form a developed resist pattern, a directional etching operation is applied to the developed resist pattern to form a trimmed resist pattern, and the underlying layer is patterned using the trimmed resist pattern as an etching mask.

A method including obtaining (i) measurements of a parameter of the feature, (ii) data related to a process variable of a patterning process, (iii) a functional behavior of the parameter defined as a function of the process variable based on the measurements of the parameter and the data related to the process variable, (iv) measurements of a failure rate of the feature, and (v) a probability density function of the process variable for a setting of the process variable, converting the probability density function of the process variable to a probability density function of the parameter based on a conversion function, where the conversion function is determined based on the function of the process variable, and determining a parameter limit of the parameter based on the probability density function of the parameter and the measurements of the failure rate.

A method and device for exposing a light-sensitive layer, said method comprising: generating at least one light ray by use of at least one light source, illuminating pixels of an exposure pattern by use of at least one micromirror device having a plurality of micromirrors with respective mirror intensity profiles, and overlaying the mirror intensity profiles of adjacent micromirrors to provide a pattern intensity profile of the exposure pattern by summing the mirror intensity profiles of each illuminated pixel of the exposure pattern.

A method includes illuminating a mirror array with light having light amplitudes forming a first greyscale pattern, the mirror array including a number of mirrors and at least two of the mirrors are illuminated with a same amplitude of the light. The method also includes imaging the light with the light amplitudes onto a substrate to create a second greyscale pattern, different than the first greyscale pattern, at the substrate.