Various embodiments of the present disclosure are directed towards a method of forming a ferroelectric memory device. In the method, a pair of source/drain regions is formed in a substrate. A gate dielectric and a gate electrode are formed over the substrate and between the pair of source/drain regions. A polarization switching structure is formed directly on a top surface of the gate electrode. By arranging the polarization switching structure directly on the gate electrode, smaller pad size can be realized, and more flexible area ratio tuning can be achieved compared to arranging the polarization switching structure under the gate electrode with the aligned sidewall and same lateral dimensions. In addition, since the process of forming gate electrode can endure higher annealing temperatures, such that quality of the ferroelectric structure is better controlled.

In some aspects of the present disclosure, a memory device includes a first memory array including: a plurality of memory strings spaced from each other along a first lateral direction and a second lateral direction, each of the plurality of memory strings including a plurality of memory cells arranged along a vertical direction; and a plurality of first conductive structures extending along the vertical direction; wherein each of the plurality of first conductive structures includes a first portion and a second portion; wherein the first portion extends across the plurality of memory cells of a corresponding pair of the plurality of memory strings along the vertical direction, and the second portion is disposed over the first portion along the vertical direction; and wherein the second portion extends farther than the first portion along at least one of the first or second lateral direction.

Ferroelectric devices, including FeFET and/or FeRAM devices, include ferroelectric material layers deposited using atomic layer deposition (ALD). By controlling parameters of the ALD deposition sequence, the crystal structure and ferroelectric properties of the ferroelectric layer may be engineered. An ALD deposition sequence including relatively shorter precursor pulse durations and purge durations between successive precursor pulses may provide a ferroelectric layer having relatively uniform crystal grain sizes and a small mean grain size (e.g., ≤3 nm), which may provide effective ferroelectric performance. An ALD deposition sequence including relatively longer precursor pulse durations and purge durations between successive precursor pulses may provide a ferroelectric layer having less uniform crystal grain sizes and a larger mean grain size (e.g., ≥7 nm). Ferroelectric layers having larger mean grain sizes may exhibit enhanced crystallinity and a stabilized orthorhombic crystal phase, particularly in relatively thin layers (e.g., ≤15 nm in thickness).

[Object] To provide a semiconductor element capable of realizing an element having a nonvolatile memory capable of stably storing highly integrated data, a nonvolatile memory device, a multiply-accumulate operation device, and a method of manufacturing the semiconductor element. [Solving means] A semiconductor element according to an embodiment of the present technology includes a plurality of cell blocks. The plurality of cell blocks are configured by connecting a plurality of cell portions in series with each other, the plurality of cell portions each having a MOSFET for controlling conduction of a channel portion and a resistor connected in parallel to the channel portion, and configured to store data by a resistance level set for each of the plurality of cell portions.

A memory device includes a transistor and a memory cell. The transistor includes a first gate electrode, a second gate electrode, a channel layer, and a gate dielectric layer. The second gate electrode is over the first gate electrode. The channel layer is located between the first gate electrode and the second gate electrode. The gate dielectric layer is located between the channel layer and the second gate electrode. The memory cell is sandwiched between the first gate electrode and the channel layer.

A memory device includes a plurality of first memory cells disposed along a vertical direction. Each of the plurality of first memory cells includes a portion of a first channel segment that extends along the vertical direction and has a first sidewall and a second sidewall. The first and second sidewalls of the first channel segment facing toward and away from a first lateral direction, respectively. Each of the plurality of first memory cells includes a portion of a first ferroelectric segment that also extends along the vertical direction and is in contact with the first sidewall of the first channel segment. A width of the first ferroelectric segment along a second lateral direction is different from a width of the first channel segment along the second lateral direction. The second lateral direction is perpendicular to the first lateral direction.

Memory cells include various versions of a capacitor structure including a polarization retention member. Each polarization retention member includes an antiferroelectric layer over a ferroelectric layer. The antiferroelectric layer, among other layers, can be tailored to customize the hysteresis loop shape, and the coercive electric field required to change polarization of the memory cell. Metal electrodes, and/or dielectric or metallic interlayers may also be employed to tailor the hysteresis. The memory cells can include FeRAMs or FeFETs. The memory cells provide a lower coercive electric field requirement compared to conventional ferroelectric memory cells, enhanced reliability, and require minimum changes to integrate into current integrated circuit fabrication processes.

A memory device includes a substrate including first and second regions, the first region having first wordlines and first bitlines, and the second region having second wordlines and second bitlines, a first memory cell array including first memory cells in the first region, the first memory cell array having volatility, and each of the first memory cells including a cell switch having a first channel region adjacent to a corresponding first wordline of the first wordlines, and a capacitor connected to the cell switch, and a second memory cell array including second memory cells in the second region, the second memory cell array having non-volatility, and each of the second memory cells including a second channel region adjacent to a corresponding second wordline of the second wordlines, and a ferroelectric layer between the corresponding second wordline of the second wordlines and the second channel region.

Semiconductor devices and methods of forming the same are provided. A semiconductor device according to the present disclosure includes a ferroelectric structure including a channel region and a source/drain region, a gate dielectric layer disposed over the channel region of the ferroelectric structure, a gate electrode disposed on the gate dielectric layer, and a source/drain contact disposed on the source/drain region of the ferroelectric structure. The ferroelectric structure includes gallium nitride, indium nitride, or indium gallium nitride. The ferroelectric structure is doped with a dopant.

A semiconductor device includes logic circuitry including a transistor disposed over a substrate, multiple layers each including metal wiring layers and an interlayer dielectric layer, respectively, disposed over the logic circuitry, and memory arrays. The multiple layers of metal wiring include, in order closer to the substrate, first, second, third and fourth layers, and the memory arrays include lower multiple layers disposed in the third layer.