A method of operating a non-volatile memory device includes performing a first sensing operation on the non-volatile memory device during a first sensing time including a first section, a second section, and a third section. The performing of the first sensing operation includes applying a first voltage level, which is variable according to a first target voltage level, to a selected word line in the first section, applying a second voltage level, which is different from the first voltage level, to the selected word line in the second section, and applying the first target voltage level, which is different from the second voltage level, to the selected word line in the third section. The first voltage level becomes greater as the first target voltage level becomes greater.

Aspects of the disclosure provide methods for determining wafer flatness and for fabricating a semiconductor device. The method includes storing a first wafer expansion of a first wafer that is collected along a first direction parallel to a working surface of the first wafer during a lithography process. The lithography process is for patterning structures on the working surface of the first wafer. Before a fabrication step with a wafer flatness requirement, a wafer flatness of the first wafer is determined based on the first wafer expansion collected during the lithography process using a flatness prediction model that is configured to predict the wafer flatness. In an example, a layer is deposited on a back side of the first wafer with a thickness that is based on the determined wafer flatness of the first wafer.

Disclosed is a semiconductor package device comprising a lower redistribution substrate, a first semiconductor chip on the lower redistribution substrate, vertical structures on the lower redistribution substrate, and a first molding member on the lower redistribution substrate and on the first semiconductor chip and the vertical structures. The vertical structure includes a first post having a first diameter, a second post on the first post and having a second diameter, and a bonding pad on the second post opposite the first post and having a third diameter. The first, second, and third diameters are different from each other. The third diameter is greater than the second diameter.

Provided herein is a semiconductor memory device and a method of manufacturing the semiconductor memory device. The semiconductor memory device includes a gate stacked body including interlayer insulating layers and conductive patterns that are alternately stacked in a vertical direction on a substrate, a channel structure penetrating at least a portion of the gate stacked body, and an upper surface of the channel structure left exposed by the gate stacked body.

A solid state drive (SSD) wafer device includes first and second semiconductor wafers coupled together. The first wafer may include a number of memory dies with die bond pads, and the second wafer may include a number of electrical interconnects, each including first and second terminals at opposed ends of the electrical interconnect. When the wafers are bonded together, the first terminals of the second wafer are bonded to the die bond pads of the memory dies of the first wafer. The second terminals are left exposed to couple with an SSD controller, which controls the transfer of data and signals between the memory dies of the first wafer and a host device such as a server in a datacenter.

A semiconductor structure includes a memory die bonded to a logic die. The memory die includes an alternating stack of insulating layers and electrically conductive layers; memory openings extending through the alternating stack, memory opening fill structures located in the memory openings and comprising a respective vertical semiconductor channel and a respective memory film, a source layer contacting the vertical semiconductor channels, a backside isolation dielectric layer contacting a backside surface of the source layer, and a source power supply mesh including a planar portion of a source-side electrically conductive layer that is located on a backside of the backside isolation dielectric layer and electrically connected to the source layer by conductive material portions that extend through the backside isolation dielectric layer.

A nonvolatile memory device includes at least one memory block and a control circuit. The at least one memory block includes a plurality of cell strings, each including a string selection transistor, a plurality of memory cells and a ground selection transistor. The control circuit controls a program operation by precharging channels of the plurality of cell strings to a first voltage during a bit-line set-up period of a program loop, applying a program voltage to a selected word-line of the plurality of cell strings during a program execution period of the program loop and after recovering voltages of the selected word-line and unselected word-lines of the plurality of cell strings to a negative voltage smaller than a ground voltage, recovering the voltages of the selected word-line and the unselected word-lines to a second voltage greater than the ground voltage during a recovery period of the program loop.

A semiconductor device includes a substrate having a first surface, a second surface opposite to the first surface, conductive connections provided on the first surface, and columnar electrodes each extending from a corresponding one of the conductive connections toward the second surface, each of the columnar electrodes having a tapered shape; and a semiconductor chip having a third surface facing the first surface and a plurality of connection bumps provided on the third surface, each of the plurality of connection bumps electrically connected to a corresponding one of the plurality of conductive connections. A first one of the columnar electrodes, located in a first region of a chip region, has a first tapered shape. A second one of the columnar electrodes, located in a second region of the chip region, has a second tapered shape different from the first tapered shape.

A semiconductor memory device includes a gate stack structure including alternately stacked interlayer insulating layers and conductive layers, a core pillar penetrating the gate stack structure, a channel layer disposed between the core pillar and the gate stack structure, a memory layer disposed between the channel layer and the gate stack structure, and a doped semiconductor part in contact with the gate stack structure. The doped semiconductor part includes a first region surrounding the core pillar up to an interface in contact with the gate stack structure and a second region extending between the memory layer and the core pillar from the first region.

A microelectronic assembly can include a substrate having first and second surfaces and an aperture extending therebetween, the substrate having terminals. The assembly can also include a first microelectronic element having a front surface facing the first surface of the substrate, a second microelectronic element having a front surface facing the first microelectronic element and projecting beyond an edge of the first microelectronic element, first and second leads electrically connecting contacts of the respective first and second microelectronic elements to the terminals, and third leads electrically interconnecting the contacts of the first and second microelectronic elements. The contacts of the first microelectronic element can be exposed at the front surface thereof adjacent the edge thereof. The contacts of the second microelectronic element can be disposed in a central region of the front surface thereof. The first, second, and third leads can have portions aligned with the aperture.