Abstract: An alternating stack of insulating layers and sacrificial material layers is formed over a substrate. A memory opening is formed through the alternating stack. A memory film is formed in the memory opening. The memory film includes an opening at a bottom portion. A connection strap is formed by performing a selective semiconductor deposition process that grows a strap semiconductor material from a physically exposed surface of an underlying semiconductor material portion through the opening. A vertical semiconductor channel is formed on an inner sidewall of the memory film by non-selectively depositing a semiconductor channel material. The connection strap provides an electrical connection between the underlying semiconductor material portion and the vertical semiconductor channel through the opening in the memory film. The sacrificial material layers are then replaced with electrically conductive layers.

Abstract: An alternating stack of insulating layers and sacrificial material layers is formed over a substrate. A memory opening is formed through the alternating stack. A memory film is formed in the memory opening. The memory film includes an opening at a bottom portion. A connection strap is formed by performing a selective semiconductor deposition process that grows a strap semiconductor material from a physically exposed surface of an underlying semiconductor material portion through the opening. A vertical semiconductor channel is formed on an inner sidewall of the memory film by non-selectively depositing a semiconductor channel material. The connection strap provides an electrical connection between the underlying semiconductor material portion and the vertical semiconductor channel through the opening in the memory film. The sacrificial material layers are then replaced with electrically conductive layers.

Abstract: A dielectric liner, a bottom conductive layer, and a stack of alternating layers including insulator layers and spacer material layers are sequentially formed over a substrate. A memory opening extending through the stack can be formed by an anisotropic etch process that employs the bottom conductive layer as an etch stop layer. The memory opening is extended downward by etching through the bottom conductive layer and the dielectric liner, while minimizing an overetch into the substrate. A memory stack structure can be formed in the memory opening. Subsequently, a backside contact trench can be formed through the stack employing the bottom conductive layer as an etch stop layer. The spacer material layers can be removed to form backside recesses, which are filled with a conductive material to form electrically conductive layers. The remaining portion of the bottom conductive layer can be employed as a source select gate electrode.

Abstract: A dielectric liner, a bottom conductive layer, and a stack of alternating layers including insulator layers and spacer material layers are sequentially formed over a substrate. A memory opening extending through the stack can be formed by an anisotropic etch process that employs the bottom conductive layer as an etch stop layer. The memory opening is extended downward by etching through the bottom conductive layer and the dielectric liner, while minimizing an overetch into the substrate. A memory stack structure can be formed in the memory opening. Subsequently, a backside contact trench can be formed through the stack employing the bottom conductive layer as an etch stop layer. The spacer material layers can be removed to form backside recesses, which are filled with a conductive material to form electrically conductive layers. The remaining portion of the bottom conductive layer can be employed as a source select gate electrode.