A memory device includes a first stacking structure, a second stacking structure, a plurality of first isolation structures, gate dielectric layers, channel layers and conductive pillars. 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.

A device includes a dielectric layer, a conductive layer, electrode layers and an oxide semiconductor layer. The dielectric layer has a first surface and a second surface opposite to the first surface. The conductive layer is disposed on the first surface of the dielectric layer. The electrode layers are disposed on the second surface of the dielectric layer. The oxide semiconductor layer is disposed in between the second surface of the dielectric layer and the electrode layers, wherein the oxide semiconductor layer comprises a material represented by formula 1 (In.sub.xSn.sub.yTi.sub.zM.sub.mO.sub.n). In formula 1, 0<x<1, 0≤y<1, 0<z<1, 0<m<1, 0<n<1, and M represents at least one metal.

A memory cell includes a transistor including a memory film extending along a word line; a channel layer extending along the memory film, wherein the memory film is between the channel layer and the word line; a source line extending along the memory film, wherein the memory film is between the source line and the word line; a first contact layer on the source line, wherein the first contact layer contacts the channel layer and the memory film; a bit line extending along the memory film, wherein the memory film is between the bit line and the word line; a second contact layer on the bit line, wherein the second contact layer contacts the channel layer and the memory film; and an isolation region between the source line and the bit line.

A semiconductor memory device includes a substrate, a stack structure disposed on the substrate, a plurality of dielectric isolation segments extending through the stack structure, and a plurality of memory cell structures. The stack structure includes a plurality of dielectric layers and a plurality of conductive layers alternatingly stacked in a Z direction substantially perpendicular to the substrate. The memory cell structures are disposed in the stack structure, and are separated from one another by the dielectric isolation segments. Each of the memory cell structures includes a pair of conductive segments each penetrating the stack structure in the Z direction, a dielectric separation segment separating the conductive segments, a conductive channel segment enclosing side surfaces of the conductive segments and the dielectric separation segment, and a memory segment enclosing side surface of the conductive channel segment and being connected between the stack structure and the conductive segment.

Some embodiments include an integrated assembly having a semiconductor structure extending from a first wiring to a second wiring. A ferroelectric transistor includes a first transistor gate adjacent a first region of the semiconductor structure. A first non-ferroelectric transistor includes a second transistor gate adjacent a second region of the semiconductor structure. The second region of the semiconductor structure is between the first region of the semiconductor structure and the first wiring. A second non-ferroelectric transistor includes a third transistor gate adjacent a third region of the semiconductor structure. The third region of the semiconductor structure is between the first region of the semiconductor structure and the second wiring.

A 3-dimensional vertical memory string array includes high-speed ferroelectric field-effect transistor (FET) cells that are low-cost, low-power, or high-density and suitable for SCM applications. The memory circuits of the present invention provide random-access capabilities. The memory string may be formed above a planar surface of substrate and include a vertical gate electrode extending lengthwise along a vertical direction relative to the planar surface and may include (i) a ferroelectric layer over the gate electrode, (ii) a gate oxide layer; (iii) a channel layer provided over the gate oxide layer, and (iv) conductive semiconductor regions embedded in and isolated from each other by an oxide layer, wherein the gate electrode, the ferroelectric layer, the gate oxide layer, the channel layer and each adjacent pair of semiconductor regions from a storage transistor of the memory string, and wherein the adjacent pair of semiconductor regions serve as source and drain regions of the storage transistor.

A memory cell includes a transistor over a semiconductor substrate. The transistor includes a ferroelectric layer arranged along a sidewall of a word line. The ferroelectric layer includes a species with valence of 5, valence of 7, or a combination thereof. An oxide semiconductor layer is electrically coupled to a source line and a bit line. The ferroelectric layer is disposed between the oxide semiconductor layer and the word line.

A three-dimensional memory device includes an alternating stack of insulating layers and electrically conductive layers located over a substrate, memory openings vertically extending through a first region of the alternating stack, memory opening fill structures located in the memory openings, and support pillar structures vertically extending through a second region of the alternating stack. Each of the support pillar structures includes a central columnar structure and a set of fins laterally protruding from the central columnar structure at levels of a subset of the electrically conductive layers.

A semiconductor device comprises a source and a pair of drains disposed on either side of the source in a first direction and spaced apart therefrom. A channel layer extending in the first direction is disposed on at least one radially outer surface of the source and the pair of drains in a second direction perpendicular to the first direction. A memory layer extending in the first direction is disposed on a radially outer surface of the channel layer in the second direction. At least one gate layer that extends in the first direction, is disposed on a radially outer surface of the memory layer in the second direction. A gate extension structure extends from the each of the drains at least part way towards the source in the first direction, and is located proximate to, and in contact with each of the channel layer and the corresponding drain.

Provided is a 3D synapse device stack, a 3D stackable synapse array using the same, and a method for manufacturing the 3D synapse device stack. The 3D synapse device stack comprises: a channel hole provided along a vertical direction on a substrate; a semiconductor body formed by applying a semiconductor material to the surface of the channel hole; first insulating layers and sources alternately stacked on a first side surface of an outer circumferential surface of the semiconductor body; first insulating layers and drains alternately stacked on a second side surface of an outer circumferential surface of the semiconductor body; a source line electrode connected to and in contact with a plurality of sources; a drain line electrode connected to and in contact with the plurality of drains; a plurality of word lines alternately stacked with first insulating layers on a third side surface of an outer circumferential surface of the semiconductor body; and a plurality of insulator stacks positioned between the word lines and the semiconductor body, wherein the semiconductor body, the source, the drain, the insulator stack, and the word line positioned on the same layer on the surface of the channel hole constitute a synapse device or a part thereof. The synapse device stack may implement an AND-type or NOR-type synapse array.