The present disclosure provides a half tone mask plate used to manufacture an active layer pattern as well as a source electrode pattern, a drain electrode pattern and a data line pattern located on the active layer pattern included in the array substrate. A surface of the array substrate includes a first region corresponding to the source electrode pattern, the drain electrode pattern and the data line pattern, a second region corresponding to a region of the active layer pattern located between the source electrode pattern and the drain electrode pattern, as well as a third region in addition to the first region and the second region; the half tone mask plate includes a semi-transparent region corresponding to the second region and a partial region of the third region.

In one embodiment, a mask set for use in fabricating thin film tunneling devices includes a first photomask configured to form bottom electrodes of the devices, the first photomask comprising a first alignment mark including multiple corner markers, and a second photomask configured to form a continuous top layer of the devices, the second photomask comprising a second alignment mark including a corner marker configured to be aligned with one of the corner markers of the first photomask, wherein a degree of overlap between the bottom electrodes and the continuous top layer depends upon the corner marker of the first photomask with which the corner marker of the second photomask aligns.

The present disclosure provides one embodiment of an IC method that includes receiving an IC design layout including a first main feature and inserting a first plurality of scattering bars in the IC design layout to form a first circular pattern of scattering bars around the first main feature. The first main feature is positioned at a center portion of the first circular pattern of scattering bars.

A mirror support module having a body that includes an internal portion surrounding an inner space, an external portion, an aperture formed in the body and an intermediate region that extends between a segment of the internal portion and the aperture. When the intermediate region is subjected to a force directed in a first direction, the intermediate region can be moved in the first direction towards the aperture to reduce an area of the aperture while the external portion remains stable regardless of movement of the intermediate region.

Provided is a photolithography method, including: a) forming a photoresist layer satisfying D=m*(λ/2n) (D is a thickness of the photoresist layer, n is a refractive index of the photoresist, λ is a wavelength of irradiated light at the time of exposure, and m is a natural number of 1 or more) on a substrate; and b) manufacturing a photoresist pattern having a ring shape by exposing the photoresist layer and developing the exposed photoresist layer using a photo mask including a transparent substrate and a plate-type metal dot contacting a light emitting surface of the transparent substrate.

Methods for reducing reticle transmission differences and for optimizing layer placement for overlay in MTRs and CTRs are disclosed. Embodiments include providing a reticle having a prime area and a frame area surrounding the prime area; determining RT differences across the prime area; and providing RT adjustment structures on the reticle to decrease the RT differences. Other embodiments include grouping multiple layers of a semiconductor production flow, the layers for each group having an RT difference less than a predetermined value; and placing the layers on plural ordered reticles of a reticle set, each reticle having multiple image fields, by selecting, for each reticle, layers from a single group and optimizing placement of the layers for overlay. Other embodiments include selectively rotating image fields on a reticle having multiple image fields to improve overlay, or optimizing placement of DDLs on CTRs by placing each design orientation on a different reticle.

Methods for reducing reticle transmission differences and for optimizing layer placement for overlay in MTRs and CTRs are disclosed. Embodiments include providing a reticle having a prime area and a frame area surrounding the prime area; determining RT differences across the prime area; and providing RT adjustment structures on the reticle to decrease the RT differences. Other embodiments include grouping multiple layers of a semiconductor production flow, the layers for each group having an RT difference less than a predetermined value; and placing the layers on plural ordered reticles of a reticle set, each reticle having multiple image fields, by selecting, for each reticle, layers from a single group and optimizing placement of the layers for overlay. Other embodiments include selectively rotating image fields on a reticle having multiple image fields to improve overlay, or optimizing placement of DDLs on CTRs by placing each design orientation on a different reticle.

A method of patterning a photoresist layer includes forming a photoresist layer on a substrate, exposing the photoresist layer to light using a first light source so as to induce a chemical change in the photoresist layer, performing a post-exposure bake process on the photoresist layer, the post-exposure bake process including irradiating the photoresist layer with at least two shots of laser light from a second light source such that the photoresist layer is heated to a first temperature, and performing a developing process on the photoresist layer after the post-exposure bake process, the development process selectively removing a portion of the photoresist layer.

A method of patterning a photoresist layer includes forming a photoresist layer on a substrate, exposing the photoresist layer to light using a first light source so as to induce a chemical change in the photoresist layer, performing a post-exposure bake process on the photoresist layer, the post-exposure bake process including irradiating the photoresist layer with at least two shots of laser light from a second light source such that the photoresist layer is heated to a first temperature, and performing a developing process on the photoresist layer after the post-exposure bake process, the development process selectively removing a portion of the photoresist layer.

Methods are disclosed to create efficient model-based Sub-Resolution Assist Features (MB-SRAF). An SRAF guidance map is created, where each design target edge location votes for a given field point on whether a single-pixel SRAF placed on this field point would improve or degrade the aerial image over the process window. In one embodiment, the SRAF guidance map is used to determine SRAF placement rules and/or to fine-tune already-placed SRAFs. The SRAF guidance map can be used directly to place SRAFs in a mask layout. Mask layout data including SRAFs may be generated, wherein the SRAFs are placed according to the SRAF guidance map. The SRAF guidance map can comprise an image in which each pixel value indicates whether the pixel would contribute positively to edge behavior of features in the mask layout if the pixel is included as part of a sub-resolution assist feature.