A semiconductor device includes a pad formed on a surface of a substrate, a bonding wire for connecting the pad to an external circuit, and a resin layer covering at least a connection portion between the pad and the bonding wire and exposing at least a part of the substrate outside the pad.

Methods of manufacturing a semiconductor package structure are provided. A method includes: bonding dies and dummy dies to a wafer; forming a dielectric material layer on the wafer to cover the dies and the dummy dies; performing a first planarization process to remove a first portion of the dielectric material layer over top surfaces of the dies and the dummy dies; and performing a second planarization process to remove portions of the dies, portions of the dummy dies and a second portion of the dielectric material layer, and a dielectric layer is formed laterally aside the dies and the dummy dies; wherein after the second planarization process is performed, a total thickness variation of the dies is less than a total thickness variation of the dummy dies.

Methods of manufacturing a semiconductor package structure are provided. A method includes: bonding dies and dummy dies to a wafer; forming a dielectric material layer on the wafer to cover the dies and the dummy dies; performing a first planarization process to remove a first portion of the dielectric material layer over top surfaces of the dies and the dummy dies; and performing a second planarization process to remove portions of the dies, portions of the dummy dies and a second portion of the dielectric material layer, and a dielectric layer is formed laterally aside the dies and the dummy dies; wherein after the second planarization process is performed, a total thickness variation of the dies is less than a total thickness variation of the dummy dies.

A package includes a semiconductor carrier, a first die, a second die, a first encapsulant, a second encapsulant, and an electron transmission path. The first die is disposed over the semiconductor carrier. The second die is stacked on the first die. The first encapsulant laterally encapsulates the first die. The second encapsulant laterally encapsulates the second die. The electron transmission path is electrically connected to a ground voltage. A first portion of the electron transmission path is embedded in the semiconductor carrier, a second portion of the electron transmission path is aside the first die and penetrates through the first encapsulant, and a third portion of the electron transmission path is aside the second die and penetrates through the second encapsulant.

A package includes a semiconductor carrier, a first die, a second die, a first encapsulant, a second encapsulant, and an electron transmission path. The first die is disposed over the semiconductor carrier. The second die is stacked on the first die. The first encapsulant laterally encapsulates the first die. The second encapsulant laterally encapsulates the second die. The electron transmission path is electrically connected to a ground voltage. A first portion of the electron transmission path is embedded in the semiconductor carrier, a second portion of the electron transmission path is aside the first die and penetrates through the first encapsulant, and a third portion of the electron transmission path is aside the second die and penetrates through the second encapsulant.

A semiconductor device including an element isolation in a trench formed in an upper surface of a semiconductor substrate, a trench isolation including a void in a trench directly under the element isolation, and a Cu wire with Cu ball connected to a pad on the semiconductor substrate, is formed. The semiconductor device has a circular trench isolation arrangement prohibition region that overlaps the end portion of the Cu ball in plan view, and the trench isolation is separated from the trench isolation arrangement prohibition region in plan view.

A semiconductor device including an element isolation in a trench formed in an upper surface of a semiconductor substrate, a trench isolation including a void in a trench directly under the element isolation, and a Cu wire with Cu ball connected to a pad on the semiconductor substrate, is formed. The semiconductor device has a circular trench isolation arrangement prohibition region that overlaps the end portion of the Cu ball in plan view, and the trench isolation is separated from the trench isolation arrangement prohibition region in plan view.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive material overlying the base structure, a stack structure overlying the doped semiconductive material, cell pillar structures vertically extending through the stack structure and the doped semiconductive material and into the base structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The base structure and portions of the cell pillar structures vertically extending into the base structure are removed to expose the doped semiconductive material. The doped semiconductive material is then patterned to form at least one source structure over the stack structure and coupled to the cell pillar structures. Microelectronic devices and electronic systems are also described.

A method of forming a microelectronic device comprises forming a microelectronic device structure comprising a base structure, a doped semiconductive material overlying the base structure, a stack structure overlying the doped semiconductive material, cell pillar structures vertically extending through the stack structure and the doped semiconductive material and into the base structure, and digit line structures vertically overlying the stack structure. An additional microelectronic device structure comprising control logic devices is formed. The microelectronic device structure is attached to the additional microelectronic device structure to form a microelectronic device structure assembly. The base structure and portions of the cell pillar structures vertically extending into the base structure are removed to expose the doped semiconductive material. The doped semiconductive material is then patterned to form at least one source structure over the stack structure and coupled to the cell pillar structures. Microelectronic devices and electronic systems are also described.

According to an exemplary embodiment of the inventive concept, there is provided a nonvolatile memory device comprising: a memory cell region including a first metal pad, a peripheral circuit region including a second metal pad and vertically connected to the memory cell region by the first metal pad and the second metal pad, a memory cell array, in the memory cell region, comprising a plurality of memory cells, a plurality of word lines and a bit line connected to the memory cells, wherein each memory cell is connected to one of the word lines, a voltage generator, in the peripheral circuit region, supplying a plurality of supply voltages to the memory cell array, a control logic circuit, in the peripheral circuit region, programming a selected one of the memory cells connected to a selected one of the word lines into a first program state by controlling the voltage generator, and a verify circuit, in the peripheral circuit region, controlling a verify operation on the memory cell array by controlling the voltage generator, wherein the verify circuit controls a word line voltage applied to at least one unselected word line not to be programmed among the plurality of word lines in the verify operation and a bit line voltage applied to the bit line connected differently from a voltage level of a voltage applied in a read operation of the nonvolatile memory device.