A semiconductor package includes a substrate including a first semiconductor chip including a first wiring structure, a first bonding pad, and a first alignment key on the first wiring structure to be spaced apart in a first direction, a second semiconductor chip including a second wiring structure, a second bonding pad on the second wiring structure and connected to the first bonding pad, and a second alignment key on the second wiring structure to be spaced apart from the second bonding pad and not overlapping the first alignment key in the second direction, the first wiring structure including a first wiring pattern connected to the first bonding pad and not overlapping the first and second alignment keys in the second direction, and the second wiring structure including a second wiring pattern connected to the second bonding pad and not overlapping the first and second alignment keys in the second direction.

This chip mounting system simultaneously images an alignment mark disposed on a substrate (WT) and an alignment mark disposed on a chip (CP), with the alignment marks disposed on the substrate (WT) and the chip (CP) being separated by a first distance at which the alignment marks fall within a depth-of-field range of imaging devices (35a, 35b). The chip mounting system calculates a relative positional deviation amount between the substrate (WT) and the chip (CP) from the imaged images of the alignment marks imaged by the imaging devices (35a, 35b) and, based on the calculated positional deviation amount, relatively moves the chip (CP) with respect to the substrate (WT) in a direction in which the positional deviation amount therebetween decreases.

A method and device for the alignment of substrates that are to be bonded. The method includes detecting and storing positions of alignment mark pairs located on surfaces of the substrates, and aligning the substrates with respect to each other in accordance with the detected positions.

A semiconductor wafer, a bonding structure, and a wafer bonding method are provided. In the semiconductor wafer, a bonding pad which is electrically connected to the interconnection structure is formed in the top cover layer, and a bonding alignment mark formed by a point array is disposed in the top cover layer. In this way, the bonding alignment mark is disposed in the top cover layer, and the top cover layer is not covered by another material layer, thereby facilitating recognition of the alignment pattern by the bonding device and increasing the alignment window in bonding process. Moreover, the bonding alignment mark is formed by a point array, thereby facilitating integration of the process for forming the bonding alignment mark with the bonding hole process and avoiding defects such as the dishing phenomenon in the manufacturing process.

A bonding structure and a method for manufacturing the same. First edge trimming is performed from the bonding surface of an n-th wafer in bonding the n-th wafer and an (n−1)th wafer, and a width of the first edge trimming is W.sub.n. As n increases, the width of the first edge trimming is gradually increased. In the trimming, a portion that is not even at the edge of the n-th wafer can be removed. The bonding surface of the n-th wafer faces the bonding surface of the (n−1)-th wafer, so as to bond the n-th wafer and the (n−1)-th wafer. Afterwards the substrate of the n-th wafer is thinned, so as to form the (n−1)-th wafer stack. There is a reduced possibility that a gap exists between the bonding interfaces of the wafers, a bonding strength between the wafers is improved, and a risk of cracking is reduced.

A package includes a carrier substrate, a first die, and a second die. The first die includes a first bonding layer, a second bonding layer opposite to the first bonding layer, and an alignment mark embedded in the first bonding layer. The first bonding layer is fusion bonded to the carrier substrate. The second die includes a third bonding layer. The third bonding layer is hybrid bonded to the second bonding layer of the first die.

According to one embodiment, a memory device includes: a first chip including a first insulating layer and a first pad; a plurality of memory units provided in a first area of the first insulating layer and arranged at first intervals in a first direction parallel to a surface of the first chip; a plurality of mark portions provided in a second area of the first insulating layer and arranged at second intervals in the first direction; a second chip including a second pad connected to the first pad and overlapping the first chip in a second direction perpendicular to the surface of the first chip; and a circuit provided in the second chip.

A method of fabricating a display device may include disposing a display panel on a stage to be parallel to an XZ-plane defined by a horizontal X-axis and a vertical Z-axis, measuring a height of a first side surface of the display panel in a direction of the Z-axis, rotating the stage such that the first side surface is parallel to a reference horizontal line in case that a result of the measured height indicates that the first side surface includes an inclined surface, moving the display panel in a direction of the Z-axis such that a first pad disposed on the first side surface overlaps the reference horizontal line, and bonding a second pad of a printed circuit board with the first pad.

A semiconductor device has a first substrate including an element region, a peripheral region that surrounds the element region, a first insulator with a first recess portion in the peripheral region, a first metal layer in the element region, and a first conductor in the peripheral region to surround the element region. A second substrate has an element region, a peripheral region that surrounds the element region, a second insulator with a second recess portion that faces the first recess portion, a second metal layer in contact with the first metal layer, and a second conductor that surrounds the element region of the second substrate.

Three-dimensional (3D) NAND memory devices and methods are provided. A fabrication method includes forming a semiconductor layer over a substrate, forming an opening that extends partially through the semiconductor layer, depositing a first stack layer and a second stack layer that are alternately stacked over a sidewall of the opening and over the semiconductor layer, and filling the opening with a dielectric material to form an alignment mark.