A semiconductor device is provided. The semiconductor device includes a first stacked structure including a plurality of first insulating patterns and a plurality of first semiconductor patterns alternately stacked on a substrate, the first stacked structure extending in a first direction parallel to an upper surface of the substrate, a first conductive pattern on one side surface of the first stacked structure, the first conductive pattern extending in a second direction crossing the upper surface of the substrate, and a first ferroelectric layer between the first stacked structure and the first conductive pattern, the first ferroelectric layer extending in the second direction, wherein each of the first semiconductor patterns includes a first impurity region, a first channel region and a second impurity region which are sequentially arranged along the first direction.

A semiconductor device includes: a first electrode; a second electrode; and a dielectric layer stack positioned between the first electrode and the second electrode, the dielectric layer stack including a first anti-ferroelectric layer, a second anti-ferroelectric layer, and a ferroelectric layer between the first anti-ferroelectric layer and the second anti-ferroelectric.

A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers, memory opening fill structures including a respective vertical semiconductor channel and a respective vertical stack of memory elements extending through the alternating stack in a memory array region, via contact structures contacting the stepped surfaces of the electrically conductive layers at each step in a staircase region, and a vertical stack of access transistors located between the staircase region and the memory array region.

The present invention provides a semiconductor memory device including a substrate, a plurality of capacitors and a supporting layer disposed on the substrate, wherein each of the capacitors is connected with at least one of the adjacent capacitors through the supporting layer. Each of the capacitors includes first electrodes, a high-k dielectric layer and a second electrode, and the high-k dielectric layer is disposed between the first electrodes and the second electrode. Due to the supporting layer directly contacts the high-k dielectric layer through a surface thereof, and the high-k dielectric layer completely covers the surface, the second electrode may be formed directly within openings with an enlarged dimension. Accordingly, the process difficulty of performing the deposition and etching processes within the openings may be reduced, and the capacitance of the capacitors is further increased.

The present invention provides a semiconductor memory device including a substrate, a plurality of capacitors and a supporting layer disposed on the substrate, wherein each of the capacitors is connected with at least one of the adjacent capacitors through the supporting layer. Each of the capacitors includes first electrodes, a high-k dielectric layer and a second electrode, and the high-k dielectric layer is disposed between the first electrodes and the second electrode. Due to the supporting layer directly contacts the high-k dielectric layer through a surface thereof, and the high-k dielectric layer completely covers the surface, the second electrode may be formed directly within openings with an enlarged dimension. Accordingly, the process difficulty of performing the deposition and etching processes within the openings may be reduced, and the capacitance of the capacitors is further increased.

A memory device includes a substrate, word line layers, insulating layers, and memory cells. The word line layers are stacked above the substrate. The insulating layers are stacked above the substrate respectively alternating with the word line layers. The memory cells are distributed along a stacking direction of the word line layers and the insulating layers perpendicularly to a major surface of the substrate. Each memory cell includes a source line electrode and a bit line electrode, a first oxide semiconductor layer, and a second oxide semiconductor layer. The first oxide semiconductor layer is peripherally surrounded by one of the word line layers, the source line electrode, and the bit line electrode. The second oxide semiconductor layer is disposed between the one of the word line layers and the first oxide semiconductor layer.

A memory device includes a substrate, word line layers, insulating layers, and memory cells. The word line layers are stacked above the substrate. The insulating layers are stacked above the substrate respectively alternating with the word line layers. The memory cells are distributed along a stacking direction of the word line layers and the insulating layers perpendicularly to a major surface of the substrate. Each memory cell includes a source line electrode and a bit line electrode, a first oxide semiconductor layer, and a second oxide semiconductor layer. The first oxide semiconductor layer is peripherally surrounded by one of the word line layers, the source line electrode, and the bit line electrode. The second oxide semiconductor layer is disposed between the one of the word line layers and the first oxide semiconductor layer.

A ferroelectric memory device includes a multi-layer stack, a channel layer and a III-V based ferroelectric layer. 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 of the multi-layer stack. The III-V based ferroelectric layer is disposed between the channel layer and the multi-layer stack, and includes at least one element selected from Group III elements, at least one element selected from Group V elements, and at least one element selected from transition metal elements.

A ferroelectric memory device includes a multi-layer stack, a channel layer and a III-V based ferroelectric layer. 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 of the multi-layer stack. The III-V based ferroelectric layer is disposed between the channel layer and the multi-layer stack, and includes at least one element selected from Group III elements, at least one element selected from Group V elements, and at least one element selected from transition metal elements.

A memory device includes a first stacking structure, a second stacking structure, a plurality of first isolation structures, gate dielectric layers, channel layers and channel layers. The first stacking structure includes a plurality of first gate layers, and a second stacking structure includes a plurality of second gate layers, where the first stacking structure and the second stacking structure are located on a substrate and separated from each other through a trench. The first isolation structures are located in the trench, where a plurality of cell regions are respectively confined between two adjacent first isolation structures of the first isolation structures in the trench, where the first isolation structures each includes a first main layer and a first liner surrounding the first main layer, where the first liner separates the first main layer from the first stacking structure and the second stacking structure. The gate dielectric layers are respectively located in one of the cell regions, and cover opposing sidewalls of the first stacking structure and the second stacking structure as well as opposing sidewalls of the first isolation structures. The channel layers respectively cover an inner surface of one of the gate dielectric layers. The conductive pillars stand on the substrate within the cell regions, and are laterally surrounded by the channel layers, where at least two of the conductive pillars are located in each of the cell regions, and the at least two conductive pillars in each of the cell regions are laterally separated from one another.