Provided are a memory device and a method of forming the same. The memory device includes a substrate, a layer stack, and a plurality of composite pillar structures. The layer stack is disposed on the substrate. The layer stack includes a plurality of conductive layers and a plurality of dielectric layers stacked alternately. The composite pillar structures respectively penetrate through the layer stack. Each composite pillar structure includes a dielectric pillar; a pair of conductive pillars penetrating through the dielectric pillar and electrically isolated from each other through a portion of the dielectric pillar; a channel layer covering both sides of the dielectric pillar and the pair of conductive pillars; a ferroelectric layer disposed between the channel layer and the layer stack; and a buffer layer disposed between the channel layer and the ferroelectric layer.

Provided are a memory device and a method of forming the same. The memory device includes a substrate, a layer stack, and a plurality of composite pillar structures. The layer stack is disposed on the substrate. The layer stack includes a plurality of conductive layers and a plurality of dielectric layers stacked alternately. The composite pillar structures respectively penetrate through the layer stack. Each composite pillar structure includes a dielectric pillar; a pair of conductive pillars penetrating through the dielectric pillar and electrically isolated from each other through a portion of the dielectric pillar; a channel layer covering both sides of the dielectric pillar and the pair of conductive pillars; a ferroelectric layer disposed between the channel layer and the layer stack; and a buffer layer disposed between the channel layer and the ferroelectric layer.

A miniaturized transistor having highly stable electrical characteristics is provided. Furthermore, high performance and high reliability of a semiconductor device including the transistor is achieved. The transistor includes a first electrode, a second electrode, a third electrode, an oxide semiconductor layer, a first insulating layer, and a second insulating layer. The transistor includes a first region and a second region surrounded by the first region. In the first region, the first insulating layer, the second electrode, the oxide semiconductor layer, and the second insulating layer are stacked. In the second region, the first electrode, the oxide semiconductor layer, the second insulating layer, and the third electrode are stacked.

Various embodiments of the present application are directed towards a metal-ferroelectric-metal-insulator-semiconductor (MFMIS) memory device, as well as a method for forming the MFMIS memory device. According to some embodiments of the MFMIS memory device, a first source/drain region and a second source/drain region are vertically stacked. An internal gate electrode and a semiconductor channel overlie the first source/drain region and underlie the second source/drain region. The semiconductor channel extends from the first source/drain region to the second source/drain region, and the internal gate electrode is electrically floating. A gate dielectric layer is between and borders the internal gate electrode and the semiconductor channel. A control gate electrode is on an opposite side of the internal gate electrode as the semiconductor channel and is uncovered by the second source/drain region. A ferroelectric layer is between and borders the control gate electrode and the internal gate electrode.

A semiconductor memory device according to an embodiment comprises: a semiconductor substrate; a stacked body having a plurality of first insulating layers and conductive layers stacked alternately on the semiconductor substrate; a columnar semiconductor layer contacting the semiconductor substrate in the stacked body being provided extending in a stacking direction of the stacked body and including a first portion and a second portion which is provided above the first portion; a memory layer provided on a side surface of the columnar semiconductor layer facing the stacked conductive layers and extending along the columnar semiconductor layer; and a second insulating layer provided between one of the first insulating layer and the conductive layers of the stacked body. The columnar semiconductor layer has a boundary of the first portion and the second portion, the boundary being close to the second insulating layer; and an average value of an outer diameter of the memory layer facing a side surface of the second insulating layer is larger than that of of the memory layer facing a side surface of a lowermost layer of the first insulating layers in the second portion.

Various embodiments comprise apparatuses and methods, such as a memory stack having a continuous cell pillar. In various embodiments, the apparatus includes a source material, a buffer material, a select gate drain (SGD), and a memory stack arranged between the source material and the SGD. The memory stack comprises alternating levels of conductor materials and dielectric materials. A continuous channel-fill material forms a cell pillar that is continuous from the source material to at least a level corresponding to the SGD.

A memory device includes source-drain structure bodies and gate structure bodies arranged along a first direction, and global word lines. The source-drain structure body includes a bit line, and first to third semiconductor layers. The first and second semiconductor layers are of first conductivity type and the first semiconductor layer is connected to the bit line. The third semiconductor layer of a second conductivity type contacts the first and second semiconductor layers. The gate structure body includes a local word line and a charge storage film. A first source-drain structure body includes a bit line forming a first reference bit line. A first global word line connects to the local word lines in the gate structure bodies formed on both sides of the first reference bit line and to the local word lines formed in alternate gate structure bodies that are formed between the remaining plurality of source-drain structure bodies.

22In a method of manufacturing a non-volatile memory device, insulating layers and conductive gates may be alternately formed on a semiconductor substrate to form a stack structure. A contact hole may be formed through the stack structure. A channel layer may be formed on a surface of the contact hole. The contact hole may be filled with a gap-fill insulating layer. The gap-fill insulating layer may be etched by a target depth to define a preliminary junction region. The channel layer may be etched until a surface of the channel layer may correspond to a surface of an uppermost gate among the gates. Diffusion-preventing ions may be implanted into the channel layer. A capping layer with impurities may be formed in the preliminary junction region.

Provided are a memory device and a method of forming the same. The memory device includes a substrate, a layer stack, and a plurality of composite pillar structures. The layer stack is disposed on the substrate. The layer stack includes a plurality of conductive layers and a plurality of dielectric layers stacked alternately. The composite pillar structures respectively penetrate through the layer stack. Each composite pillar structure includes a dielectric pillar; a pair of conductive pillars penetrating through the dielectric pillar and electrically isolated from each other through a portion of the dielectric pillar; a channel layer covering both sides of the dielectric pillar and the pair of conductive pillars; a ferroelectric layer disposed between the channel layer and the layer stack; and a buffer layer disposed between the channel layer and the ferroelectric layer.

A device includes a multi-layer stack, a channel layer, a ferroelectric layer and buffer layers. The multi-layer stack is disposed on a substrate and includes a plurality of conductive layers and a plurality of dielectric layers stacked alternately. The channel layer penetrates through the plurality of conductive layers and the plurality of dielectric layers. The ferroelectric layer is disposed between the channel layer and each of the plurality of conductive layers and the plurality of dielectric layers. The buffer layers include a metal oxide, and one of the buffer layers is disposed between the ferroelectric layer and each of the plurality of dielectric layers.