Provided is a stacked semiconductor package including a package base substrate including a plurality of signal wires and at least one power wire, wherein a plurality of top downsurface connecting pads and a plurality of bottom surface connecting pads are on a top surface and a bottom surface of the package base substrate, respectively; and a plurality of semiconductor chips that are sequentially stacked on the package base substrate and are electrically connected to the top surface connecting pads, the plurality of semiconductor chips including a first semiconductor chip that is a bottommost semiconductor chip, and a second semiconductor chip that is on the first semiconductor chip, wherein the signal wires are arranged apart from a portion of the package base substrate, the first portion that overlaps a first edge of the first semiconductor chip, the first edge overlapping the second semiconductor chip in a vertical direction.

A semiconductor structure includes a memory die bonded to a support die. The memory die includes an alternating stack of insulating layers and electrically conductive layers located over a first single crystalline semiconductor layer, and memory stack structures extending through the alternating stack and containing respective memory film and a respective vertical semiconductor channel including a single crystalline channel semiconductor material. The support die includes a peripheral circuitry.

A semiconductor device includes a first semiconductor die, a second semiconductor die including a side surface bonded to the first semiconductor die, such that the second semiconductor die is perpendicular to the first semiconductor die, and a junction circuit for connecting the first semiconductor die to the second semiconductor die.

A method including stacking a number of silicon dice such that one or more edges of the dice are in vertical alignment, where the one or more edges include a number of connection pads. The method also includes positioning a connecting wire on a substantially perpendicular axis to the one or more edges. The connecting wire includes a number of solder blocks formed thereon. The solder blocks are spaced at intervals associated with a distance between a first set of aligned connection pads on the dice. The connecting wire is positioned such that the solder blocks are in contact with the first set of aligned connection pads. The method also includes applying heat to cause the solder blocks to reflow and physically and electrically couple the connecting wire to the connection pads.

A system for interconnecting at least two die each die having a plurality of conducting layers and dielectric layers disposed upon a substrate which may include active and passive elements. In one embodiment there is at least one interconnect coupling at least one conducting layer on a side of one die to at least one conducting layer on a side of the other die. Another interconnect embodiment is a slug having conducting and dielectric layers disposed between two or more die to interconnect between the die. Other interconnect techniques include direct coupling such as rod, ball, dual balls, bar, cylinder, bump, slug, and carbon nanotube, as well as indirect coupling such as inductive coupling, capacitive coupling, and wireless communications. The die may have features to facilitate placement of the interconnects such as dogleg cuts, grooves, notches, enlarged contact pads, tapered side edges and stepped vias.

A semiconductor device is disclosed including one or more stacks of semiconductor dies vertically molded together in an encapsulated block. The semiconductor dies may comprise memory dies, or memory dies and a controller die.

A method including stacking a number of silicon dice such that one or more edges of the dice are in vertical alignment, where the one or more edges include a number of connection pads. The method also includes positioning a connecting wire on a substantially perpendicular axis to the one or more edges. The connecting wire includes a number of solder blocks formed thereon. The solder blocks are spaced at intervals associated with a distance between a first set of aligned connection pads on the dice. The connecting wire is positioned such that the solder blocks are in contact with the first set of aligned connection pads. The method also includes applying heat to cause the solder blocks to reflow and physically and electrically couple the connecting wire to the connection pads.

A stack of electrical components has a first electrical component having a first surface, a second surface that is opposite to the first surface and a side surface that is located between the first surface and the second surface; a second electrical component having a third surface on which the first electrical component is mounted, the third surface facing the second surface and forming a corner portion between the third surface and the side surface; an adhesive layer that bonds the first electrical component to the second electrical component, the adhesive layer has a first portion that is located between the second and third surface and a second portion that is made of a same material as the first portion and that fills the corner portion; and a conductive layer that extends on a side of the side surface, curves along the second portion and extends to the third surface.

The present invention is intended to provide a semiconductor module and a DIMM module that are capable of stably supplying power to a plurality of stacked memory chips, a manufacturing method of the semiconductor module and a manufacturing method of the DIMM module. The semiconductor module 1 having a plurality of memory chips 21 includes: a memory substrate 10 having a power supply circuit 12 exposed on an arrangement surface as one surface of the memory substrate 10; and at least one memory unit 20 arranged over the arrangement surface of the memory substrate 10. The memory unit 20 includes: the plurality of memory chips 21 stacked together such that a stacking direction D is along the arrangement surface; a through electrode 22 passing through the plurality of memory chips 21 in the stacking direction D; and an electrode layer 23 formed on one end surface in the stacking direction D and connected to the through electrode 22 and the power supply circuit 12.

A system for interconnecting at least two die each die having a plurality of conducting layers and dielectric layers disposed upon a substrate which may include active and passive elements. In one embodiment there is at least one interconnect coupling at least one conducting layer on a side of one die to at least one conducting layer on a side of the other die. Another interconnect embodiment is a slug having conducting and dielectric layers disposed between two or more die to interconnect between the die. Other interconnect techniques include direct coupling such as rod, ball, dual balls, bar, cylinder, bump, slug, and carbon nanotube, as well as indirect coupling such as inductive coupling, capacitive coupling, and wireless communications. The die may have features to facilitate placement of the interconnects such as dogleg cuts, grooves, notches, enlarged contact pads, tapered side edges and stepped vias.