Abstract: A semiconductor memory device includes a substrate, a stack disposed on the substrate, a vertical channel structure penetrating the stack, and a fixed charge layer disposed in the vertical channel structure. The stack includes insulating patterns and gate electrodes alternately and repeatedly disposed on one another. The vertical channel structure includes a data storing pattern.

Abstract: A method of manufacturing a three-dimensional semiconductor memory device comprises forming a thin layer structure by alternately stacking first and second material layers on a substrate, forming a penetration dent penetrating the thin layer structure and exposing a top surface of the substrate recessed by the penetration dent, forming a vertical insulation layer penetrating the thin layer structure to cover an inner wall of the penetration dent, forming a semiconductor pattern penetrating the vertical insulation layer at the penetration dent to be inserted into the substrate, and forming an oxide layer between the thin layer structure and the substrate by oxidizing a sidewall of the penetration dent.

Abstract: A method of manufacturing a three-dimensional semiconductor memory device comprises forming a thin layer structure by alternately stacking first and second material layers on a substrate, forming a penetration dent penetrating the thin layer structure and exposing a top surface of the substrate recessed by the penetration dent, forming a vertical insulation layer penetrating the thin layer structure to cover an inner wall of the penetration dent, forming a semiconductor pattern penetrating the vertical insulation layer at the penetration dent to be inserted into the substrate, and forming an oxide layer between the thin layer structure and the substrate by oxidizing a sidewall of the penetration dent.

Abstract: One embodiment exemplarily described herein can be generally characterized as a semiconductor device that includes a lower level device layer located over a semiconductor substrate, an interlayer insulating film located over the lower level device layer and an upper level device layer located over the interlayer insulating film. The lower level device layer may include a plurality of devices formed in the substrate. The upper level device layer may include a plurality of semiconductor patterns and at least one device formed in each of the plurality of semiconductor patterns. The plurality of semiconductor patterns may be electrically isolated from each other. Each of the plurality of semiconductor patterns may include at least one active portion and at least one body contact portion electrically connected to the at least one active portion.

Abstract: A stack-type semiconductor device and a method of manufacturing the same are provided. The stack-type semiconductor device includes an insulation layer on a single-crystalline substrate, a contact plug penetrating the insulation layer to contact the single-crystalline substrate, an upper semiconductor pattern including an impurity region and a gate structure positioned between the impurity regions on the upper semiconductor pattern. An upper surface of the contact plug contacts a lower surface of the semiconductor pattern. An operation failure of the stack-type semiconductor device is reduced since the upper semiconductor pattern is electrically connected to the single-crystalline semiconductor substrate.

Abstract: A driving method of a three-dimensional memory device having a plurality of layers is provided. One of the layers is selected. A well of the selected layer is biased with a first well voltage. A word line voltage is applied to a selected word line of the selected layer. A well of an unselected layer is biased with a second well voltage higher than the first well voltage.

Abstract: A stack-type semiconductor device and a method of manufacturing the same are provided. The stack-type semiconductor device includes an insulation layer on a single-crystalline substrate, a contact plug penetrating the insulation layer to contact the single-crystalline substrate, an upper semiconductor pattern including an impurity region and a gate structure positioned between the impurity regions on the upper semiconductor pattern. An upper surface of the contact plug contacts a lower surface of the semiconductor pattern. An operation failure of the stack-type semiconductor device is reduced since the upper semiconductor pattern is electrically connected to the single-crystalline semiconductor substrate.

Abstract: One embodiment exemplarily described herein can be generally characterized as a semiconductor device that includes a lower level device layer located over a semiconductor substrate, an interlayer insulating film located over the lower level device layer and an upper level device layer located over the interlayer insulating film. The lower level device layer may include a plurality of devices formed in the substrate. The upper level device layer may include a plurality of semiconductor patterns and at least one device formed in each of the plurality of semiconductor patterns. The plurality of semiconductor patterns may be electrically isolated from each other. Each of the plurality of semiconductor patterns may include at least one active portion and at least one body contact portion electrically connected to the at least one active portion.

Abstract: A driving method of a three-dimensional memory device having a plurality of layers is provided. One of the layers is selected. A well of the selected layer is biased with a first well voltage. A word line voltage is applied to a selected word line of the selected layer. A well of an unselected layer is biased with a second well voltage higher than the first well voltage.