A semiconductor chip includes a chip body, a redistribution layer pattern disposed on a surface of the chip body, an alignment mark pattern disposed to be spaced apart from the redistribution layer pattern on the surface of the chip body, a first insulating pattern disposed to contact a side surface of the redistribution layer pattern and a side surface of the alignment mark pattern on the surface of the chip body, a second insulating pattern disposed on the redistribution layer pattern to protect the redistribution layer pattern, and an alignment mark protection pattern disposed on the alignment mark pattern.

A semiconductor device including: a first silicon level including a first single crystal silicon layer and a plurality of first transistors; a first metal layer disposed over the first silicon level; a second metal layer disposed over the first metal layer; a third metal layer disposed over the second metal layer; a second level including a plurality of second transistors, the second level disposed over the third metal layer; a fourth metal layer disposed over the second level; a fifth metal layer disposed over the fourth metal layer, where the fourth metal layer is aligned to the first metal layer with a less than 40 nm alignment error; a via disposed through the second level, where each of the second transistors includes a metal gate, where a typical thickness of the second metal layer is greater than a typical thickness of the third metal layer by at least 50%.

A method of partitioning a wafer includes defining a scribe line surrounding a set of dies. The method further includes etching a plurality of trenches into the wafer, wherein each trench of the plurality of trenches is located between adjacent dies of the set of dies, and a width of each trench of the plurality of trenches is less than a width of the scribe line. The method further includes thinning the wafer to expose a bottom surface of the plurality of trenches. The method further includes cutting along the scribe line to separate the set of dies from another portion of the wafer.

A semiconductor device, including: a first memory cell including a first transistor; a second memory cell including a second transistor, where the second transistor overlays the first transistor and the second transistor self-aligned to the first transistor; and a plurality of junctionless transistors, where at least one of the junctionless transistors controls access to at least one of the memory cells.

A mark is formed over the surface of a silicon substrate. The mark includes a silicon oxide film, in which a plurality of rectangular groove patterns are concentrically arranged, and a silicon nitride film formed in the groove patterns. A P-type epitaxial layer is formed over the surface of the silicon substrate. Then, a photoresist pattern is formed. In the photoresist pattern, a rectangular opening pattern is formed in a mark region. Optical superposition inspection is performed for the base of the photoresist pattern.

A 3D semiconductor device including: a first level including a plurality of first metal layers; a second level, where the second level overlays the first level, where the second level includes at least one single crystal silicon layer, where the second level includes a plurality of transistors, where each transistor of the plurality of transistors includes a single crystal channel, where the second level includes a plurality of second metal layers, where the plurality of second metal layers include interconnections between the transistors of the plurality of transistors, and where the second level is overlaid by a first isolation layer; and a connective path between the plurality of transistors and the plurality of first metal layers, where the connective path includes a via disposed through at least the single crystal silicon layer, and where the via includes contact with at least one of the plurality of transistors.

The present application discloses a semiconductor device with integrated decoupling alignment features. The semiconductor device includes a first wafer comprising a first substrate having a dielectric stack, a decoupling feature positioned in the dielectric stack under one of the plurality of first alignment marks, a plurality of first alignment marks positioned on the first substrate and parallel to each other; and a second wafer positioned on the first wafer and comprising a plurality of second alignment marks positioned above the plurality of first alignment marks. The plurality of second alignment marks are arranged parallel to the plurality of first alignment marks and adjacent to the plurality of first alignment marks in a top-view perspective. The plurality of first alignment marks and the plurality of second alignment marks comprise a fluorescence material. The decoupling feature has a is bottle-shaped cross-sectional profile, and the decoupling feature comprises a porous low-k material.

The present application discloses a method for fabricating a semiconductor device with integrated decoupling alignment features. The method includes providing a first substrate; forming a plurality of first alignment marks on the first substrate and parallel to each other, wherein the first substrate and the plurality of first alignment marks together configure a first wafer; providing a second wafer comprising a plurality of second alignment marks parallel to each other; and bonding the second wafer onto the first wafer. The plurality of second alignment marks are arranged parallel to the plurality of first alignment marks and adjacent to the plurality of first alignment marks in a top-view perspective. The plurality of first alignment marks and the plurality of second alignment marks comprise a fluorescence material.

When opaque films are deposited on semi-conductor wafers, underlying features may be concealed. In accordance with one implementation, such concealed features may be re-exposed via an ablation recovery process. One ablation recovery process entails aligning an energy source with a target position on a first surface of a semiconductor wafer based on position information retrieved from a second opposite surface of the semiconductor wafer, and firing a beam of the energy source to ablate opaque material at the target position and to expose a recovery feature underlying the opaque material.

A recognition method for photolithography process and a semiconductor device are provided. The recognition method includes forming a mask layer on a semiconductor substrate, and then patterning the mask layer to form multiple dense line patterns in a cell region and multiple dummy dense line patterns in an interface region between the cell region and a peripheral region. At least one connection portion is provided between a first and a third dummy dense line patterns, and a second dummy dense line pattern is discontinuous at and separated from the at least one connection portion. A photoresist layer covering the peripheral region is formed on the semiconductor substrate, and whether a landing position of the photoresist layer is correct is determined according to a distance from an edge of the photoresist layer to a closest dummy dense line pattern and a width of the at least one connection portion.