A product includes a semiconductor substrate, with at least first and second thin-film layers disposed on the substrate and patterned to define a matrix of dies, which are separated by scribe lines and contain active areas circumscribed by the scribe lines. A plurality of overlay targets are formed in the first and second thin-film layers within each of the active areas, each overlay target having dimensions no greater than 10 μm×10 μm in a plane parallel to the substrate. The plurality of overlay targets include a first linear grating formed in the first thin-film layer and having a first grating vector, and a second linear grating formed in the second thin-film layer, in proximity to the first linear grating, and having a second grating vector parallel to the first grating vector.

A substrate film forming machine table and a usage method. The substrate film forming machine table comprises: a first substrate bearing inlet and outlet chamber; a second substrate bearing inlet and outlet chamber; a film forming chamber; an intermediate chamber; a pump set connected to the first substrate bearing inlet and outlet chamber; a second pump connected to the intermediate chamber; a third pump connected to the film forming chamber and the second substrate bearing inlet and outlet chamber; at least one backup pump, which is provided to connect to the film forming chamber and the second substrate bearing inlet and outlet chamber so as to extract air from the film forming chamber and the second substrate bearing inlet and outlet chamber when the third pump is damaged; or, connecting to the intermediate chamber so as to extract air from the intermediate chamber when the second pump is damaged.

A method of characterizing asymmetric depositions on a target is provided. The method includes forming at least four asymmetrical petals in a layer on a substrate, and depositing a light-absorbing material on the at least four asymmetrical petals, wherein the light-absorbing material deposits unevenly on a plurality of walls of the at least four asymmetrical petals. The method further includes determining a pattern shift response (PSR) from the light-absorbing material on each of the walls of the at least four asymmetrical petals, and converting the pattern shift response (PSR) to an asymmetry of thicknesses of the light-absorbing material deposited on facing walls of the at least four asymmetrical petals. The method further includes correcting an overlay petal position based on the asymmetry of thicknesses.

Embodiments of the present disclosure relate to methods for defect inspection. After pattern features are formed in a structure layer, a dummy filling material having dissimilar optical properties from the structure layer is filled in the pattern features. The dissimilar optical properties between materials in the pattern features and the structure layer increase contrast in images captured by an inspection tool, thus increasing the defect capture rate.

A display device includes a display panel having a display area and a non-display area. A window is disposed on the display panel. A bezel portion is disposed on the window. The bezel portion at least partially overlaps the non-display area. An adhesive layer is disposed between the display panel and the window. An interlayer is disposed between the bezel portion and the adhesive layer. The interlayer has at least one ultrasound transmitting area overlapping the bezel portion.

An enclosure surrounding the optical component can be connected with a vapor source. The vapor source can provide a vapor to the enclosure with a vapor level from 500 ppm to 15000 ppm. The concentration of vapor in the enclosure can increase the lifespan of the optical component in the enclosure.

According to various embodiments, a semiconductor memory device includes a substrate that includes a memory cell region and a test region. The semiconductor memory device further includes an active pattern on the memory cell region, a source/drain pattern on the active pattern, a dummy pattern on the test region, a first gate electrode on the dummy pattern, a first common contact, and a first wiring layer. The first wiring layer includes a first test line electrically connected to the first common contact. The first common contact includes a first contact pattern in contact with the dummy pattern, and a first gate contact connected to the first gate electrode. The first gate contact includes a body and a protrusion part. A lowermost level of a top surface of the active pattern is lower than a lowermost level of a top surface of the dummy pattern.

An electron beam apparatus is provided. The apparatus comprises an e-beam source configured to generate an electron beam, a first part configured to support a substrate, the first part comprising an object table for supporting the substrate, the first part further comprising a short stroke actuator system for actuating the object table relative to the e-beam source, the short stroke actuator system comprising a short stroke forcer. The apparatus further comprises a second part configured to movably support the first part and a long stroke actuator system configured to actuate movement of the first part with respect to the second part, the long stroke actuator system comprising a long stroke forcer, wherein the short stroke forcer and/or the long stroke forcer is configured to be switched off while the electron beam is projected onto the substrate.

According to one embodiment, a registration mark includes a first step portion and a second step portion. The first step portion includes a plurality of first steps which descend step by step in a first direction from a surface of a substrate or a layer formed on the substrate. The second step portion includes a plurality of second steps which descend step by step from the surface in a second direction different from the first direction and have the same number as the number of the plurality of first steps, is spaced apart from the first step portion, and is disposed rotationally symmetrically to the first step portion.

Provided is a display panel, including a through hole, an isolation area, and a display area. The isolation area is around the through hole. The isolation area is between the through hole and the display area. The isolation area includes at least two graphic marks for detecting the hole accuracy of the through hole. The at least two graphic marks are spaced apart from each other around the through holes. Graphic marks are arranged in an isolation area of a display panel. The isolation area is between a through hole and a display area. That is, the graphic marks are around the through hole.