Disclosed are a 3D non-volatile memory, an operating method thereof, and a manufacturing method thereof. The 3D non-volatile memory includes a bit line formed to extend in a vertical direction and horizontal structures contacting the bit line while being formed to extend in a horizontal direction and being space in the vertical direction. Each of the horizontal structures includes a ferroelectric layer contacting the bit line, a middle metal layer surrounded by the ferroelectric layer, a dielectric layer surrounded by the middle metal layer, and a word line surrounded by the dielectric layer.

A capacitor is provided which comprises: a first structure comprising metal; a second structure comprising metal; and a third structure between the first and second structures, wherein the third structure comprises an improper ferroelectric material. In some embodiments, a field effect transistor (FET) is provided which comprises: a substrate; a source and drain adjacent to the substrate; and a gate stack between the source and drain, wherein the gate stack includes: a dielectric; a first structure comprising improper ferroelectric material, wherein the first structure is adjacent to the dielectric; and a second structure comprising metal, wherein the second structure is adjacent to the first structure.

A semiconductor memory structure includes a semiconductor layer, a conductive layer disposed over the semiconductor layer, a gate penetrating through the conductive layer and the semiconductor layer, and an interposing layer disposed between the gate and the conductive layer and between the gate and the semiconductor layer, wherein a pair of channel regions is formed in the semiconductor layer at two sides of the gate.

A novel semiconductor device is provided. A memory string, which extends in the Z direction and includes a conductor and an oxide semiconductor, intersects with a plurality of wirings CG extending in the Y direction. The conductor is placed along a center axis of the memory string, and the oxide semiconductor is concentrically placed outside the conductor. The conductor is electrically connected to the oxide semiconductor. An intersection portion of the memory string and the wiring CG functions as a transistor. In addition, the intersection portion functions as a memory cell.

Systems and methods for reducing the impact of defects within a crossbar memory array when performing multiplication operations in which multiple control lines are concurrently selected are described. A group of memory cells within the crossbar memory array may be controlled by a local word line that is controlled by a local word line gating unit that may be configured to prevent the local word line from being biased to a selected word line voltage during an operation; the local word line may instead be set to a disabling voltage during the operation such that the memory cell currents through the group of memory cells are eliminated. If a defect has caused a short within one of the memory cells of the group of memory cells, then the local word line gating unit may be programmed to hold the local word line at the disabling voltage during multiplication operations.

Some embodiments include a ferroelectric transistor having a conductive gate structure, a first ring extending around the conductive gate structure and a second ring extending around the first ring. The first ring includes ferroelectric material. The second ring includes insulative material. A mass of channel material is outward of the second ring. Some embodiments include integrated assemblies and methods of forming integrated assemblies.

A memory device includes a memory cell and a controller. The memory cell includes: (a) an array of molecule chains, at least one molecule chain includes: (i) first and second binding sites positioned at first and second ends of the molecule chain, respectively, and (ii) a chain of one or more fullerene derivatives, chemically connecting between the first and second binding sites, (b) source and drain electrodes, electrically connected to the first and second binding sites, respectively, and configured to apply to the array a source-drain voltage (VSD) along a first axis, and (c) a gate electrode, configured to apply to the array a gate voltage (VG) along a second different axis. The controller is configured to perform a data storage operation in the memory cell by (i) applying to the gate electrode a signal for producing the VG, and (ii) applying the VSD between the source and drain electrodes.

A memory cell includes a ferroelectric (FE) material contacting a word line; and an oxide semiconductor (OS) layer contacting a source line and a bit line, wherein the FE material is disposed between the OS layer and the word line. The OS layer comprises: a first region adjacent the FE material, the first region having a first concentration of a semiconductor element; a second region adjacent the source line, the second region having a second concentration of the semiconductor element; and a third region between the first region and the second region, the third region having a third concentration of the semiconductor element, the third concentration is greater than the second concentration and less than the first concentration.

Provided are an electronic device and a method of manufacturing the same. The electronic device may include a first device provided on a first region of a substrate; and a second device provided on a second region of the substrate, wherein the first device may include a first domain layer including a ferroelectric domain and a first gate electrode on the first domain layer, and the second device may include a second domain layer including a ferroelectric domain and a second gate electrode on the second domain layer. The first domain layer and the second domain layer may have different characteristics from each other at a polarization change according to an electric field. At the polarization change according to the electric field, the first domain layer may have substantially a non-hysteretic behavior characteristic and the second domain layer may have a hysteretic behavior characteristic.

Some embodiments include a ferroelectric transistor having a conductive gate structure, a first ring extending around the conductive gate structure and a second ring extending around the first ring. The first ring includes ferroelectric material. The second ring includes insulative material. A mass of channel material is outward of the second ring. Some embodiments include integrated assemblies and methods of forming integrated assemblies.