A method for forming a semiconductor memory structure includes following operations. A plurality of doped regions are formed in a semiconductor substrate. The doped regions are separated from each other. A stack including a plurality of first insulating layers and a plurality of second insulating layers alternately arranged is formed over the semiconductor substrate. A first trench is formed in the stack. The second insulating layers are replaced with a plurality of conductive layers. A second trench is formed. A charge-trapping layer and a channel layer are formed in the second trench. An isolation structure is formed to fill the second trench. A source structure and a drain structure are formed at two sides of the isolation structure.

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.

Described herein are memory cells that include two transistors stacked above one another above a support structure where neither one of the transistors is coupled to a capacitor and where at least one of the two transistors is a thin-film transistor. In such 2T capacitorless memory cells, a first transistor may be referred to a write transistor, and a second transistor may be a read transistor. The first transistor may be a three-terminal device having two S/D terminals and a gate terminal, while the second transistor may be a four-terminal device having two S/D terminals and two gate terminals.

Reliability of a semiconductor device including a ferroelectric memory is improved. A gate electrode of a ferroelectric memory is formed on a semiconductor substrate so as to arrange a ferroelectric film therebetween, and a semiconductor layer serving as an epitaxial semiconductor layer is formed on the semiconductor substrate on both sides of the gate electrode. The semiconductor layer is formed on a dent portion of the semiconductor substrate. At least a part of each of a source region and a drain region of the ferroelectric memory is formed in the semiconductor layer.

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 memory structure includes storage transistors organized as horizontal NOR memory strings where the storage transistors are thin-film ferroelectric field-effect transistors (FeFETs) having a ferroelectric gate dielectric layer formed adjacent an oxide semiconductor channel region. The ferroelectric storage transistors thus formed are junctionless transistors having no p/n junction in the channel. In some embodiments, the ferroelectric storage transistors in each NOR memory string share a common source line and a common bit line, the common source line and the common bit line formed on a first side of the channel region and the ferroelectric gate dielectric layer and in electrical contact with the oxide semiconductor channel region. The ferroelectric storage transistors in a NOR memory string are controlled by individual control gate electrodes formed on a second side, opposite the first side, of the ferroelectric gate dielectric layer.

A memory structure includes storage transistors organized as horizontal NOR memory strings where the storage transistors are thin-film ferroelectric field-effect transistors (FeFETs) having a ferroelectric gate dielectric layer formed adjacent an oxide semiconductor channel region. The ferroelectric storage transistors thus formed are junctionless transistors having no p/n junction in the channel. In some embodiments, the ferroelectric storage transistors in each NOR memory string share a common source line and a common bit line that are formed on a first side of the channel region, away from the ferroelectric gate dielectric layer, and in electrical contact with the oxide semiconductor channel region. The ferroelectric storage transistors in a NOR memory string are controlled by individual control gate electrodes that are formed adjacent the ferroelectric gate dielectric layer on a second side, opposite the first side, of the channel region.

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.

The present disclosure relates to an integrated circuit (IC) in which a memory structure comprises a ferroelectric structure without critical-thickness limitations. The memory structure comprises a first electrode and the ferroelectric structure. The ferroelectric structure is vertically stacked with the first electrode and comprises a first ferroelectric layer, a second ferroelectric layer, and a first restoration layer. The second ferroelectric layer overlies the first ferroelectric layer, and the first restoration layer is between and borders the first and second ferroelectric layers. The first restoration layer is a different material type than that of the first and second ferroelectric layers and is configured to decouple crystalline lattices of the first and second ferroelectric layers so the first and second ferroelectric layers do not reach critical thicknesses. A critical thickness corresponds to a thickness at and above which the orthorhombic phase becomes thermodynamically unstable, such that remanent polarization is lost.

A memory cell, an integrated circuit and method of manufacturing the same are provided. The memory device includes a substrate, gate layers and insulating layers, an isolation column, a channel layer, a first conductive feature, a second conductive feature, a storage layer and a pair of isolation structures. The isolation column extends through the gate layers and the insulating layers along a first direction. The channel layer laterally covers the isolation column. The first conductive feature and second conductive feature extend along the first direction and adjacent to the isolation column. The storage layer is disposed between the gate layers and the channel layer. The pair of isolation structures extends along the first direction. The pair of isolation structures includes a first isolation structure disposed between the first conductive feature and the gate layers, and a second isolation structure disposed between the second conductive feature and the gate layers.