A 3D semiconductor device, the device including: a first level; and a second level, where the first level includes single crystal silicon and a plurality of logic circuits, where the second level is disposed above the first level and includes a plurality of arrays of memory cells, where the single crystal silicon includes an area, and where the area is greater than 1,000 mm.sup.2.

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.

Alignment of a first wafer bonded to a second wafer can be determined using electrical wafer alignment methods. A wafer stack can be formed by overlaying a second wafer over a first wafer such that second metal bonding pads of the second wafer contact first metal bonding pads of the first wafer. A leakage current or a capacitance measurement step is performed between first alignment diagnostic structures in the first wafer and second alignment diagnostic structures in the second wafer for multiple mating pairs of first semiconductor dies in the first wafer and second semiconductor dies in the second wafer to determine the alignment.

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 bonding system includes a first holder and a second holder arranged to be spaced apart from each other in a vertical direction; a position adjuster configured to move the first holder and the second holder relatively to perform a position adjustment in a horizontal direction between a first substrate held by the first holder and a second substrate held by the second holder; a pressing unit configured to press the first substrate and the second substrate against each other; a measuring unit configured to measure a position deviation between an alignment mark on the first substrate and an alignment mark on the second substrate, the first substrate and the second substrate being bonded by the pressing unit; and a position adjustment controller configured to control the position adjustment in the horizontal direction in a currently-performed bonding processing based on the position deviation generated in a previously-performed bonding processing.

A semiconductor package includes: a first semiconductor chip including a plurality of front surface pads disposed on a first active surface of a first semiconductor substrate, at least one penetrating electrode penetrating at least a portion of the first semiconductor substrate and connected to the front surface pads, a first rear surface cover layer disposed on a first inactive surface of the first semiconductor substrate, a first rear surface dummy conductive layer penetrating a portion of the first rear surface cover layer; a second semiconductor chip including a second front surface cover layer disposed on a second active surface of a second semiconductor substrate, and a second front surface dummy conductive layer penetrating a portion of the second front surface cover layer; and at least one first bonded pad penetrating the first rear surface cover layer and the second front surface cover layer.

A flip-chip bonding method includes following operations. A wafer is provided with multiple semiconductor dies on an adhesive film held by a frame element. A semiconductor die is lifted up from the wafer by an ejector element. The semiconductor die is picked up with a collector element. The semiconductor die is flip-chipped with the collector element. An alignment check is performed to determine a position of the semiconductor die, so as to determine a process tolerance between a center of the collector element and a center of the semiconductor die. The semiconductor die with the collector element is transferred to a location underneath a bonder element based on the process tolerance of the alignment check. The semiconductor die is picked up from the collector element by the bonder element. The semiconductor die is bonded to a carrier by the bonder element.

A method includes determining a first offset between a first alignment mark on a first side of a first wafer and a second alignment mark on a second side of the first wafer; aligning the first alignment mark of the first wafer to a third alignment mark on a first side of a second wafer, which includes detecting a location of the second alignment mark of the first wafer; determining a location of the first alignment mark of the first wafer based on the first offset and the location of the second alignment mark of the first wafer; and, based on the determined location of the first alignment mark, repositioning the first wafer to align the first alignment mark to the third alignment mark; and bonding the first side of the first wafer to the first side of the second wafer to form a bonded structure.

A method includes providing a first wafer including a respective set of first metal bonding pads and at least one first alignment diagnostic structure, providing a second wafer including a respective set of second metal bonding pads and a respective set of second alignment diagnostic structures, overlaying the first wafer and the second wafer, measuring at least one of a current, voltage or contact resistance between the first alignment diagnostic structures and the second alignment diagnostic structures to determine an overlay offset, and bonding the second wafer to the first wafer.

A semiconductor device including a first die and a second die bonded to one another. The first die includes a first passivation layer over a substrate, and first bond pads in the first passivation layer. The second die includes a second passivation layer, which may be bonded to the first passivation layer, and second bond pads in the second passivation layer, which may be bonded to the first bond pads. The second bond pads include inner bond pads and outer bond pads. The outer bond pads may have a greater diameter than the inner bond pads as well as the first bond pads.