A semiconductor package includes a semiconductor die and an encapsulant layer. A mark is formed on a surface of the encapsulant layer. A damage barrier layer is disposed between the mark and the semiconductor die. The damage barrier layer blocks the propagation of laser light used to form the mark from reaching the semiconductor die.

A semiconductor package includes a semiconductor die and an encapsulant layer. A mark is formed on a surface of the encapsulant layer. A damage barrier layer is disposed between the mark and the semiconductor die. The damage barrier layer blocks the propagation of laser light used to form the mark from reaching the semiconductor die.

A memory device includes an array of memory cells configured on a die or chip and coupled to sense lines and access lines of the die or chip and a respective sense amplifier configured on the die or chip coupled to each of the sense lines. Each of a plurality of subsets of the sense lines is coupled to a respective local input/output (I/O) line on the die or chip for communication of data on the die or chip and a respective transceiver associated with the respective local I/O line, the respective transceiver configured to enable communication of the data to one or more device off the die or chip.

To help reduce program disturbs in non-selected NAND strings of a non-volatile memory, a sub-block based boosting scheme in introduced. For a three dimensional NAND memory structure, in which the memory cells above a joint region form an upper sub-block and memory cells below the joint region form a lower sub-block, dummy word lines in the joint region act as select gates to allow boosting at the sub-block level when the lower block is being programmed in a reverse order.

To help reduce program disturbs in non-selected NAND strings of a non-volatile memory, a sub-block based boosting scheme in introduced. For a three dimensional NAND memory structure, in which the memory cells above a joint region form an upper sub-block and memory cells below the joint region form a lower sub-block, dummy word lines in the joint region act as select gates to allow boosting at the sub-block level when the lower block is being programmed in a reverse order.

A memory device includes first and second semiconductor layers. The first semiconductor layer includes wordlines and bitlines, an upper substrate, and a memory cell array. The memory cell array includes a memory blocks. The second semiconductor layer includes a lower substrate, and an address decoder. Each memory block includes a core region including a memory cells, a first extension region adjacent to a first side of the core region and including a plurality of wordline contacts, and a second extension region adjacent to a second side of the core region and including an insulating mold structure. The second extension region includes step zones and at least one flat zone. Through-hole vias penetrating the insulating mold structure are in the flat zone. The wordlines and the address decoder are electrically connected with each other by at least the through-hole vias.

A memory device includes first and second semiconductor layers. The first semiconductor layer includes wordlines and bitlines, an upper substrate, and a memory cell array. The memory cell array includes a memory blocks. The second semiconductor layer includes a lower substrate, and an address decoder. Each memory block includes a core region including a memory cells, a first extension region adjacent to a first side of the core region and including a plurality of wordline contacts, and a second extension region adjacent to a second side of the core region and including an insulating mold structure. The second extension region includes step zones and at least one flat zone. Through-hole vias penetrating the insulating mold structure are in the flat zone. The wordlines and the address decoder are electrically connected with each other by at least the through-hole vias.

A semiconductor package includes a package substrate including an insulating layer having an upper surface and a lower surface and provided with a first region which is recessed to a first depth from the upper surface toward the lower surface, a redistribution wiring buried in the insulating layer, a chip connection pad on a bottom surface of the recessed first region and connected to the redistribution wiring, and a wire connection pad on the upper surface of the insulating layer and connected to the redistribution wiring, a first semiconductor chip overlapping, in a top-down view of the semiconductor package, the recessed first region of the insulating layer and comprising a first chip pad connected to the chip connection pad of the package substrate, and a second semiconductor chip on the first semiconductor chip and connected to the wire connection pad of the package substrate through a conductive wire.

A semiconductor package includes a package substrate including an insulating layer having an upper surface and a lower surface and provided with a first region which is recessed to a first depth from the upper surface toward the lower surface, a redistribution wiring buried in the insulating layer, a chip connection pad on a bottom surface of the recessed first region and connected to the redistribution wiring, and a wire connection pad on the upper surface of the insulating layer and connected to the redistribution wiring, a first semiconductor chip overlapping, in a top-down view of the semiconductor package, the recessed first region of the insulating layer and comprising a first chip pad connected to the chip connection pad of the package substrate, and a second semiconductor chip on the first semiconductor chip and connected to the wire connection pad of the package substrate through a conductive wire.

A semiconductor device having a substrate, a semiconductor chip, and a plurality of electrode terminals is provided. The substrate has first and second principal surfaces. The semiconductor chip is disposed on the first principal surface. The electrode terminals are disposed on the second principal surface. The substrate has a via interconnection near a position at which an outer edge line of the semiconductor chip intersects an outer outline of the electrode terminal farthest from a center of the substrate, the electrode terminal farthest from the center of the substrate being among the plurality of electrode terminals overlapping the outer edge line in a predetermined condition as seen through the substrate of the semiconductor device from a direction perpendicular to the first principal surface, the via interconnection connecting a first interconnection layer on a first principal surface-side to a second interconnection layer on a second principal surface-side.