A method of forming a memory device includes: forming a first layer stack and a second layer stack successively over a substrate, the first layer stack and the second layer stack having a same layered structure that includes a dielectric material, a channel material over the dielectric material, and a source/drain material over the channel material; forming openings that extend through the first layer stack and the second layer stack; forming inner spacers by replacing portions of the source/drain material exposed by the openings with a first dielectric material; lining sidewalls of the openings with a ferroelectric material; forming gate electrodes by filling the openings with an electrically conductive material; forming a recess through the first layer stack and the second layer stack, the recess extending from a sidewall of the second layer stack toward the gate electrodes; and filling the recess with a second dielectric material.

A memory circuit includes a memory array including a plurality of memory cells, each memory cell including a gate structure including a ferroelectric layer and a channel layer adjacent to the gate structure, the channel layer including a metal oxide material. A driver circuit is configured to output a gate voltage to the gate structure of a memory cell, the gate voltage having a positive polarity and a first magnitude in in a first write operation and a negative polarity and a second magnitude in in a second write operation, and to control the second magnitude to be greater than the first magnitude.

An alternating stack of first material layers and second material layers can be formed over a semiconductor material layer. A patterning film is formed over the alternating stack, and openings are formed through the patterning film. Via openings are formed through the alternating stack at least to a top surface of the semiconductor material layer by performing a first anisotropic etch process that transfers a pattern of the openings in the patterning film. A cladding liner can be formed on a top surface of the patterning film and sidewalls of the openings in the pattering film. The via openings can be vertically extended through the semiconductor material layer at least to a bottom surface of the semiconductor material layer by performing a second anisotropic etch process employing the cladding liner as an etch mask.

According to various aspects, a memory cell is provided, the memory cell may include a field-effect transistor; a first control node and a second control node, a first capacitor structure including a first electrode connected to the first control node, a second electrode connected to a gate region of the field-effect transistor, and a remanent-polarizable region disposed between the first electrode and the second electrode of the first capacitor structure; and a second capacitor structure including a first electrode connected to the second control node, a second electrode connected to the gate region of the field-effect transistor. In some aspects, the first capacitor structure may have a first capacitance and the second capacitor structure may have a second capacitance different from the first capacitance.

The present disclosure provides a semiconductor structure, including: a first layer including a logic device; and a second layer over the first layer, including a first type memory device, a though silicon via (TSV) electrically connecting the logic device and the first type memory device. A method of forming semiconductor structure is also disclosed.

A ferroelectric field-effect transistor (FeFET) includes first and second gate electrodes, source and drain regions, a semiconductor region between and physically connecting the source and drain regions, a first gate dielectric between the semiconductor region and the first gate electrode, and a second gate dielectric between the semiconductor region and the second gate electrode. The first gate dielectric includes a ferroelectric dielectric. In an embodiment, a memory cell includes this FeFET, with the first gate electrode being electrically connected to a wordline and the drain region being electrically connected to a bitline. In another embodiment, a memory array includes wordlines extending in a first direction, bitlines extending in a second direction, and a plurality of such memory cells at crossing regions of the wordlines and the bitlines. In each memory cell, the wordline is a corresponding one of the wordlines and the bitline is a corresponding one of the bitlines.

A semiconductor device includes a substrate including an active region extending in a first direction, a gate electrode on the substrate and extending in a second direction, and a plurality of channel layers on the active region. The plurality of channel layers are spaced apart from each other in a third direction perpendicular to an upper surface of the substrate. The device includes a plurality of dielectric layers between the plurality of channel layers and the gate electrode, the plurality of dielectric layers include at least one of a ferroelectric material or an anti-ferroelectric material, and each of the plurality of dielectric layers has a different coercive voltage. The device includes source/drain regions in recess regions in which the active region is recessed, the source/drain regions are on both sides of the gate electrode, and the source/drain regions are in contact with the plurality of channel layers.

A semiconductor device includes a substrate including an active region extending in a first direction, a gate electrode on the substrate and extending in a second direction, and a plurality of channel layers on the active region. The plurality of channel layers are spaced apart from each other in a third direction perpendicular to an upper surface of the substrate. The device includes a plurality of dielectric layers between the plurality of channel layers and the gate electrode, the plurality of dielectric layers include at least one of a ferroelectric material or an anti-ferroelectric material, and each of the plurality of dielectric layers has a different coercive voltage. The device includes source/drain regions in recess regions in which the active region is recessed, the source/drain regions are on both sides of the gate electrode, and the source/drain regions are in contact with the plurality of channel layers.

Semiconductor devices may include a stacked structure including interlayer insulating layers and gate electrodes alternately stacked in a vertical direction, a core region extending in the vertical direction in the stacked structure, a channel layer on a side surface of the core region and facing the gate electrodes and the interlayer insulating layers, a first dielectric layer, a data storage layer and a second dielectric layer, which are between the channel layer and the gate electrodes in order, and an anti-ferroelectric layer including a portion interposed between the first dielectric layer and a first gate electrode of the gate electrodes. The second dielectric layer may contact the channel layer. The anti-ferroelectric layer may be formed of an anti-ferroelectric material having a tetragonal phase.

Semiconductor devices may include a stacked structure including interlayer insulating layers and gate electrodes alternately stacked in a vertical direction, a core region extending in the vertical direction in the stacked structure, a channel layer on a side surface of the core region and facing the gate electrodes and the interlayer insulating layers, a first dielectric layer, a data storage layer and a second dielectric layer, which are between the channel layer and the gate electrodes in order, and an anti-ferroelectric layer including a portion interposed between the first dielectric layer and a first gate electrode of the gate electrodes. The second dielectric layer may contact the channel layer. The anti-ferroelectric layer may be formed of an anti-ferroelectric material having a tetragonal phase.