A memory device including at least one dummy word line over a substrate; a plurality of word lines over the dummy word line; and a plurality of vertical holes extending through the at least one dummy word line and the plurality of word lines in a direction perpendicular to the substrate and classified into channel holes and dummy holes, each of the channel holes being connected to a bit line. The method including performing an erase operation on dummy cells formed as the dummy word line and the dummy holes; verifying the erase operation; and performing a program operation on at least one of the dummy cells such that the at least one dummy cell has a higher threshold voltage than main cells formed as the dummy word line and the channel holes.

A memory device including at least one dummy word line over a substrate; a plurality of word lines over the dummy word line; and a plurality of vertical holes extending through the at least one dummy word line and the plurality of word lines in a direction perpendicular to the substrate and classified into channel holes and dummy holes, each of the channel holes being connected to a bit line. The method including performing an erase operation on dummy cells formed as the dummy word line and the dummy holes; verifying the erase operation; and performing a program operation on at least one of the dummy cells such that the at least one dummy cell has a higher threshold voltage than main cells formed as the dummy word line and the channel holes.

Semiconductor device packages may include a first semiconductor device over a substrate and a second semiconductor device over the first semiconductor device. An active surface of the second semiconductor device may face away from the substrate. Electrical interconnections may extend from bond pads of the second semiconductor device, along surfaces of the second semiconductor device, first semiconductor device, and substrate to pads of routing members of the substrate. The electrical interconnections may include conductors in contact with the bond pads and the routing members and a dielectric material interposed between the conductors and the first semiconductor device, the second semiconductor device and the substrate between the bond pads and the pad of the routing members. An encapsulant distinct from the dielectric material may cover the electrical interconnections, the first semiconductor device, the second semiconductor device, and an upper surface of the substrate. Methods of fabrication are also disclosed.

Semiconductor device packages may include a first semiconductor device over a substrate and a second semiconductor device over the first semiconductor device. An active surface of the second semiconductor device may face away from the substrate. Electrical interconnections may extend from bond pads of the second semiconductor device, along surfaces of the second semiconductor device, first semiconductor device, and substrate to pads of routing members of the substrate. The electrical interconnections may include conductors in contact with the bond pads and the routing members and a dielectric material interposed between the conductors and the first semiconductor device, the second semiconductor device and the substrate between the bond pads and the pad of the routing members. An encapsulant distinct from the dielectric material may cover the electrical interconnections, the first semiconductor device, the second semiconductor device, and an upper surface of the substrate. Methods of fabrication are also disclosed.

A discrete three-dimensional (3-D) processor comprises first and second dice. The first die comprises 3-D memory (3D-M) arrays, whereas the second die comprises logic circuits and at least an off-die peripheral-circuit component of the 3D-M array(s). The first die does not comprise the off-die peripheral-circuit component. The first and second dice are communicatively coupled by a plurality of inter-die connections. The preferred discrete 3-D processor can be applied to mathematical computing, computer simulation, configurable gate array, pattern processing and neural network.

A discrete three-dimensional (3-D) processor comprises first and second dice. The first die comprises 3-D memory (3D-M) arrays, whereas the second die comprises logic circuits and at least an off-die peripheral-circuit component of the 3D-M array(s). The first die does not comprise the off-die peripheral-circuit component. The first and second dice are communicatively coupled by a plurality of inter-die connections. The preferred discrete 3-D processor can be applied to mathematical computing, computer simulation, configurable gate array, pattern processing and neural network.

The present disclosure provides a manufacturing method of a die-stack structure including follow steps. A first wafer including a first die is provided, wherein the first die includes a first substrate material layer, a first interconnect structure, and a first pad, and the first interconnect structure and the first pad are formed on the first substrate material layer in order, and the first substrate material layer has a first contact conductor disposed therein. a first contact conductor is disposed in the first substrate material layer. A second wafer including a second die is provided, wherein the second die includes a second substrate material layer, a second interconnect structure, and a second pad, and the second interconnect structure and the second pad are formed on the second substrate material layer in order, and the second substrate material layer has a second contact conductor disposed therein. A portion of the first substrate material layer is removed to form a first substrate, wherein the first contact conductor is exposed to a surface of the first substrate away from the first interconnect structure. The second wafer is covered on the first substrate such that the first contact conductor is directly physically in contact with the second pad.

The present disclosure is directed to a package that includes openings that extend into the package. The openings are filled with a conductive material to electrically couple a first die in the package to a second die in the package. The conductive material that fills the openings forms electrical interconnection bridges between the first die and the second die. The openings in the package may be formed using a laser and a non-doped molding compound, a doped molding compound, or a combination of doped or non-doped molding compounds.

The present disclosure is directed to a package that includes openings that extend into the package. The openings are filled with a conductive material to electrically couple a first die in the package to a second die in the package. The conductive material that fills the openings forms electrical interconnection bridges between the first die and the second die. The openings in the package may be formed using a laser and a non-doped molding compound, a doped molding compound, or a combination of doped or non-doped molding compounds.

A chip package structure is provided. The chip package structure includes a first substrate. The chip package structure includes a conductive via structure passing through the first substrate. The chip package structure includes a barrier layer over a surface of the first substrate. The chip package structure includes an insulating layer over the barrier layer. The chip package structure includes a conductive pad over the insulating layer and having a first portion and a second portion. The chip package structure includes a conductive bump over the second portion of the conductive pad. A third portion of the conductive pad is between the conductive bump and the conductive via structure from a top view of the conductive pad, the conductive bump, and the conductive via structure.