A three-dimensional semiconductor memory device includes stacked structures, vertical semiconductor patterns, common source regions, and well pickup regions. The stacked structures are disposed on a semiconductor layer of a first conductivity type. Each stacked structure includes electrodes vertically stacked on each other and is extended in a first direction. The vertical semiconductor patterns penetrate the stacked structures. The common source regions of a second conductivity type are disposed in the semiconductor layer. At least one common source region is disposed between two adjacent stacked structures. The at least one common source region is extended in the first direction. The well pickup regions of the first conductivity type are disposed in the semiconductor layer. At least one well pickup region is adjacent to both ends of at least one stacked structure.

Methods and structures of a three-dimensional memory device are disclosed. In an example, the memory device comprises a substrate, a stack structure on the substrate, and at least one gate line slit extending along a first direction substantially parallel to a top surface of the substrate, and dividing the stack structure into at least two portions. The stack structure includes at least one connection portion that divides the at least one gate line slit, and conductively connects the at least two portions.

A memory device includes gate electrode layers stacked on an upper surface of a substrate and each including a plurality of unit electrodes extending in a first direction, and a plurality of connecting electrodes connecting the unit electrodes to each other. The memory device also includes channel structures extending through the gate electrode layers in a direction perpendicular to the upper surface of the substrate, first common source lines extending in the first direction and interposed between the unit electrodes, and second common source lines extending in the first direction between the first common source lines and each having a first line and a second line separated from each other in the first direction by the connecting electrodes.

A non-volatile memory device and a method of manufacturing the same are provided. The device includes a substrate including a cell region and a peripheral region, a gate pattern formed over the substrate in the peripheral region, a multilayered structure formed over the gate pattern in the peripheral region, the multilayered structure including interlayer insulating layers and material layers for sacrificial layers, and a capping layer formed between the gate pattern and the multilayered structure in the peripheral region to cover the substrate, the capping layer configured to prevent diffusion of impurities from the material layers for the sacrificial layers into the substrate in the peripheral region.

A method of concurrently etching a first region in which silicon oxide films and silicon nitride films are alternately stacked and a second region including the silicon oxide film having a thickness larger than a thickness of the silicon oxide film of the first region is provided. The method includes generating plasma of a first processing gas containing a fluorocarbon gas and a hydrofluorocarbon gas within a processing vessel of a plasma processing apparatus into which a processing target object is carried; and generating plasma of a second processing gas containing a hydrogen gas, a hydrofluorocarbon gas and a nitrogen gas within the processing vessel of the plasma processing apparatus. Further, the generating of the plasma of the first processing gas and the generating of the plasma of the second processing gas are repeated alternately.

According to an embodiment, a nonvolatile semiconductor memory device comprises a plurality of conductive layers stacked in a first direction via an inter-layer insulating layer. In addition, the nonvolatile semiconductor memory device comprises: a semiconductor layer having the first direction as a longer direction; a tunnel insulating layer contacting a side surface of the semiconductor layer; a charge accumulation layer contacting a side surface of the tunnel insulating layer; and a block insulating layer contacting a portion facing the conductive layer, of a side surface of the charge accumulation layer. Moreover, the portion facing the conductive layer, of the charge accumulation layer is thinner compared to a portion facing the inter-layer insulating layer, of the charge accumulation layer.

Provided is an etching method for simultaneously etching first and second regions of a workpiece. The first region has a multilayered film configured by alternately laminating a silicon oxide film and a silicon nitride film and a second region has a silicon oxide film having a film thickness that is larger than that of the silicon oxide film in the first region. A mask is provided on the workpiece to at least partially expose each of the first and second regions. In the etching method, plasma of a first processing gas containing fluorocarbon gas, hydrofluorocarbon gas, and oxygen gas is generated within a processing container of a plasma processing apparatus. Subsequently, plasma of a second processing gas containing fluorocarbon gas, hydrofluorocarbon gas, oxygen gas, and a halogen-containing gas is generated within the processing container. Subsequently, plasma of a third processing gas containing oxygen gas is generated within the processing container.

Some embodiments include a memory device and methods of forming the memory device. One such memory device includes a first group of memory cells, each of the memory cells of the first group being formed in a cavity of a first control gate located in one device level of the memory device. The memory device also includes a second group of memory cells, each of the memory cells of the second group being formed in a cavity of a second control gate located in another device level of the memory device. Additional apparatus and methods are described.

Vertical memory devices, and methods of manufacturing the same, include providing a substrate including a cell array region and a peripheral circuit region, forming a mold structure in the cell array region, forming an opening for a common source line passing through the mold structure and extending in a first direction perpendicular to a top surface of the substrate, forming a first contact plug having an inner sidewall delimiting a recessed region in the opening for the common source line, and forming a common source bit line contact electrically connected to the inner sidewall of the first contact plug.

A memory film and a semiconductor channel can be formed within each memory opening that extends through a stack including an alternating plurality of insulator layers and sacrificial material layers. After formation of backside recesses through removal of the sacrificial material layers selective to the insulator layers, a metallic barrier material portion can be formed in each backside recess. A molybdenum-containing portion can be formed in each backside recess. Each backside recess can be filled with a molybdenum-containing portion alone, or can be filled with a combination of a molybdenum-containing portion and a metallic material portion including a material other than molybdenum.