Multiple bonded units are provided, each of which includes a respective front-side die and a backside die. The two dies in each bonded unit may be a memory die and a logic die configured to control operation of memory elements in the memory die. Alternatively, the two dies may be memory dies. The multiple bonded units can be attached such that front-side external bonding pads have physically exposed surfaces that face upward and backside external bonding pads of each bonded unit have physically exposed surfaces that face downward. A first set of bonding wires can connect a respective pair of front-side external bonding pads, and a second set of bonding wires can connect a respective pair of backside external bonding pads.

Semiconductor die stacks, and associated methods and systems are disclosed. The semiconductor die stack may include a first die with a memory array and a second die with CMOS circuitry configured to access the memory array. The first die may not have circuitry for accessing the memory array. Further, the first and second dies may be bonded to function as a single memory device, and front surfaces of the first and second dies are conjoined to form electrical connections therebetween. The second die may include a portion uncovered by the first die, where bond pads of the semiconductor die stack are located. The first die may provide a space for bond wires to connect to the bond pads without interfering with another die attached above the semiconductor die stack. Multiple semiconductor die stacks may be stacked on top of and in line with each other.

Semiconductor die stacks, and associated methods and systems are disclosed. The semiconductor die stack may include a first die with a memory array and a second die with CMOS circuitry configured to access the memory array. The first die may not have circuitry for accessing the memory array. Further, the first and second dies may be bonded to function as a single memory device, and front surfaces of the first and second dies are conjoined to form electrical connections therebetween. The second die may include a portion uncovered by the first die, where bond pads of the semiconductor die stack are located. The first die may provide a space for bond wires to connect to the bond pads without interfering with another die attached above the semiconductor die stack. Multiple semiconductor die stacks may be stacked on top of and in line with each other.

A chip structure includes a substrate, a bottom conductive layer, a semiconductor layer, an interlayer dielectric layer, at least one electrode, and at least one top electrode. The substrate includes in order a core layer and a composite material. The bottom conductive layer is disposed on the bottom surface of the core layer, the semiconductor layer is disposed on the substrate, and an interlayer dielectric layer is disposed on the semiconductor layer. The at least one electrode is disposed between the semiconductor layer and the interlayer dielectric layer, and the at least one top electrode is disposed on the interlayer dielectric layer and electrically coupled to the at least one electrode.

A chip structure includes a substrate, a bottom conductive layer, a semiconductor layer, an interlayer dielectric layer, at least one electrode, and at least one top electrode. The substrate includes in order a core layer and a composite material. The bottom conductive layer is disposed on the bottom surface of the core layer, the semiconductor layer is disposed on the substrate, and an interlayer dielectric layer is disposed on the semiconductor layer. The at least one electrode is disposed between the semiconductor layer and the interlayer dielectric layer, and the at least one top electrode is disposed on the interlayer dielectric layer and electrically coupled to the at least one electrode.

Interconnected substrate arrays, microelectronic packages, and methods for fabricating microelectronic packages for fabricating microelectronic packages utilizing interconnected substrate arrays containing integrated electrostatic discharge (ESD) protection grids are provided. In an embodiment, the method includes obtaining an interconnected substrate array having an integrated ESD protection grid. The ESD protection grid includes, in turn, ESD grid lines at least partially formed in singulation streets of an interconnected substrate array and electrically coupling die attachment regions of the substrate array to one or more peripheral machine ground contacts. Array-level fabrication steps are performed to produce an interconnected package array utilizing the interconnected substrate array, while electrically coupling the die attachment regions to electrical ground through the ESD protection grid during at least one of the array-level fabrication steps. Afterwards, the interconnected package array is singulated to yield a plurality of singulated microelectronic packages.

Interconnected substrate arrays, microelectronic packages, and methods for fabricating microelectronic packages for fabricating microelectronic packages utilizing interconnected substrate arrays containing integrated electrostatic discharge (ESD) protection grids are provided. In an embodiment, the method includes obtaining an interconnected substrate array having an integrated ESD protection grid. The ESD protection grid includes, in turn, ESD grid lines at least partially formed in singulation streets of an interconnected substrate array and electrically coupling die attachment regions of the substrate array to one or more peripheral machine ground contacts. Array-level fabrication steps are performed to produce an interconnected package array utilizing the interconnected substrate array, while electrically coupling the die attachment regions to electrical ground through the ESD protection grid during at least one of the array-level fabrication steps. Afterwards, the interconnected package array is singulated to yield a plurality of singulated microelectronic packages.

A semiconductor device and electronic system, the device including a cell structure stacked on a peripheral circuit structure, wherein the cell structure includes a first interlayer dielectric layer and first metal pads exposed at the first interlayer dielectric layer and connected to gate electrode layers and channel regions, the peripheral circuit structure includes a second interlayer dielectric layer and second metal pads exposed at the second interlayer dielectric layer and connected to a transistor, the first metal pads include adjacent first and second sub-pads, the second metal pads include adjacent third and fourth sub-pads, the first and third sub-pads are coupled, and a width of the first sub-pad is greater than that of the third sub-pad, and the second sub-pad and the fourth sub-pad are coupled, and a width of the fourth sub-pad is greater than that of the second sub-pad.

A semiconductor device and electronic system, the device including a cell structure stacked on a peripheral circuit structure, wherein the cell structure includes a first interlayer dielectric layer and first metal pads exposed at the first interlayer dielectric layer and connected to gate electrode layers and channel regions, the peripheral circuit structure includes a second interlayer dielectric layer and second metal pads exposed at the second interlayer dielectric layer and connected to a transistor, the first metal pads include adjacent first and second sub-pads, the second metal pads include adjacent third and fourth sub-pads, the first and third sub-pads are coupled, and a width of the first sub-pad is greater than that of the third sub-pad, and the second sub-pad and the fourth sub-pad are coupled, and a width of the fourth sub-pad is greater than that of the second sub-pad.

A nonvolatile memory device including a substrate extending in a first direction, a ground selection line extending in the first direction on the substrate, a plurality of word lines stacked sequentially on the ground selection line and extending in the first direction, a landing pad spaced apart from the ground selection line and the plurality of word lines in the first direction, a rear contact plug connected to a lower face of the landing pad and extending in a second direction intersecting the first direction, a front contact plug connected to an upper face of the landing pad opposite the lower face and extending in the second direction, an input/output pad electrically connected to the rear contact plug, and an upper bonding pad electrically connected to the front contact plug and connected to at least a part of a plurality of circuit elements of the nonvolatile memory device.