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.

A method of forming alignment marks, each alignment mark including a plurality of fiducials, includes providing a III-V compound substrate having a device region and an alignment mark region. The method also includes forming a first hardmask in the device region and a hardmask structure in the alignment mark region, etching a first surface portion of the III-V compound substrate to form a plurality of trenches in the device region, and epitaxially regrowing a semiconductor layer in the trenches. The method further includes forming a second mask in the device region and a patterned structure in the alignment mark region. The patterned structure includes a set of masked regions corresponding to the plurality of fiducials and a second set of openings. The method also includes forming the plurality of fiducials.

The present disclosure is related to a method of forming a pattern, including the steps of: providing a structure including a substrate and a target layer, in which the target layer is disposed on the substrate, and the target layer includes a central area and a periphery area; forming a plurality of core patterns and a linear spacer pattern on the central area, in which a width of the linear spacer pattern is wider than 50 nm; covering a photoresist on the periphery area; removing a portion of the central area not covered by the plurality of core patterns and not covered by the linear spacer pattern to form a pattern in the central area, and removing the photoresist, the linear spacer pattern and the plurality of core patterns to expose the pattern.

The reflectance of a low-reflectance alignment mark is increased by coating the alignment mark with a high-reflectance film layer. This improves the strength of the light signal and reduces variation in the light signal.

According to one embodiment, a pattern forming method includes forming a resist film including a first core material pattern and a second core material pattern, on a first film laminated on a substrate; forming a second film at least on sidewalls of the first and second core material patterns; removing the first core material pattern while not removing the second core material pattern and the second film; and processing the first film by using, as a mask, the second core material pattern and the second film.

At a motherboard for an image device, which is used for manufacturing an image device such as a liquid crystal device, an organic electroluminescence device, a mirror device, and an image-capturing device, a mark for alignment is provided on an outer side of a pixel area in which a plurality of pixels are arranged. In the photo-lithography process, a light exposure mask is arranged by using the mark as a reference position. For the mark, a recessed portion provided in a motherboard main body is filled with a filling film. The recessed portion includes a first groove extending along a first direction and a second groove extending along a second direction intersecting with the first direction, the second groove not intersecting with the first groove in plan view.

A method for applying a deposition model in a semiconductor manufacturing process. The method includes predicting a deposition profile of a substrate using the deposition model; and using the predicted deposition profile to enhance a metrology target design. The deposition model can be calibrated using experimental cross-section profile information from a layer of a physical substrate. In some embodiments, the deposition model is a machine-learning model, and calibrating the deposition model includes training the machine-learning model. The metrology target design may include an alignment metrology target design or an overlay metrology target design, for example.

A method of configuring a mark having a trench to be etched into a substrate, the method including: obtaining a relation between an extent of height variation across a surface of a probationary layer deposited on a probationary trench of a probationary depth and a thickness of the probationary layer; determining an extent of height variation across the surface of a layer deposited on the mark allowing a metrology system to determine a position of the mark; and configuring the mark by determining a depth of the trench based on the relation, the extent of height variation and the thickness of a process layer to be deposited on the mark.

The present application provides an alignment method for backside photolithography process of the wafer, the alignment method includes: cutting the wafer, and using at least two edges formed by cutting as the first alignment mark; bonding the front side of the wafer to the wafer pad to form a composite wafer; aligning the first alignment mark with the corresponding second alignment mark on the photomask for backside photolithography. This method is not limited by wafer thickness and material, and reduces the secondary input of the photolithography equipment; meanwhile, the probability of fragments of thin wafers in the photolithography process can be reduced, and the yield of the product is effectively improved.

A method for manufacturing semiconductor devices include steps of depositing a first photoresist over a first dielectric layer, first exposing the first photoresist to a first light-exposure using a first lithographic mask, and second exposing the first photoresist to a second light-exposure using a second lithographic mask. An overlap region of the first photoresist is exposed to both the first light-exposure and the second light-exposure. The first dielectric layer is thereafter patterned to form a mask overlay alignment mark in the overlap region. The patterning includes etching the first dielectric layer form a trench, and filling the trench with a conductive material to produce the alignment mark. A second dielectric layer is deposited over the alignment mark, and a second photoresist is deposited over the second dielectric layer. A third lithographic mask is aligned to the second photoresist using the underlying mask overlay alignment mark for registration.