Various embodiments of the present application are directed towards a metal-ferroelectric-metal-insulator-semiconductor (MFMIS) memory device, as well as a method for forming the MFMIS memory device. According to some embodiments of the MFMIS memory device, a first source/drain region and a second source/drain region are vertically stacked. An internal gate electrode and a semiconductor channel overlie the first source/drain region and underlie the second source/drain region. The semiconductor channel extends from the first source/drain region to the second source/drain region, and the internal gate electrode is electrically floating. A gate dielectric layer is between and borders the internal gate electrode and the semiconductor channel. A control gate electrode is on an opposite side of the internal gate electrode as the semiconductor channel and is uncovered by the second source/drain region. A ferroelectric layer is between and borders the control gate electrode and the internal gate electrode.

In an embodiment, a device includes: a first dielectric layer having a first sidewall; a second dielectric layer having a second sidewall; a word line between the first dielectric layer and the second dielectric layer, the word line having an outer sidewall and an inner sidewall, the inner sidewall recessed from the outer sidewall, the first sidewall, and the second sidewall; a memory layer extending along the outer sidewall of the word line, the inner sidewall of the word line, the first sidewall of the first dielectric layer, and the second sidewall of the second dielectric layer; and a semiconductor layer extending along the memory layer.

Routing arrangements for 3D memory arrays and methods of forming the same are disclosed. In an embodiment, a memory array includes a ferroelectric (FE) material contacting a first word line; an oxide semiconductor (OS) layer contacting a source line and a bit line, the FE material being disposed between the OS layer and the first word line; a dielectric material contacting the FE material, the FE material being between the dielectric material and the first word line; an inter-metal dielectric (IMD) over the first word line; a first contact extending through the IMD to the first word line, the first contact being electrically coupled to the first word line; a second contact extending through the dielectric material and the FE material; and a first conductive line electrically coupling the first contact to the second contact.

A tridimensional memory cell array includes vertically stacked first conductive lines, vertically stacked second conductive lines, and first and second flights of steps. First and second conductive lines extend along a first direction. The second conductive lines are disposed at a distance along a second direction from the first conductive lines. First and second directions are orthogonal. Along the first direction, the first flights are disposed at opposite ends of the first conductive lines and the second flights are disposed at opposite ends of the second conductive lines. The first and second flights include landing pads and connective lines alternately disposed along the first direction. The landing pads are wider than the connective lines along the second direction. Along the second direction, landing pads of the first flights face connective lines of the second flights and landing pads of the second flights face connective lines of the first flights.

A semiconductor memory device capable of improving performance by the use of a charge storage layer including a ferroelectric material is provided. The semiconductor memory device includes a substrate, a tunnel insulating layer contacting the substrate, on the substrate, a charge storage layer contacting the tunnel insulating layer and including a ferroelectric material, on the tunnel insulating layer, a barrier insulating layer contacting the charge storage layer, on the charge storage layer, and a gate electrode contacting the barrier insulating layer, on the barrier insulating layer.

A semiconductor structure includes vertically-alternating stacks of insulating strips and electrically conductive strips located over a substrate and laterally spaced apart from each other by line trenches. Laterally-alternating sequences of semiconductor region assemblies and dielectric pillar structures are located within a respective one of the line trenches. Memory films are located between each neighboring pair of the vertically-alternating stacks and the laterally-alternating sequences. Each of the semiconductor region assemblies includes a source pillar structure, a drain pillar structure, and a channel structure including a pair of lateral semiconductor channels that laterally connect the source pillar structure and the drain pillar structure. The memory films may include a charge storage layer or a ferroelectric material layer.

Provided are a memory device and a method of forming the same. The memory device includes a substrate, a multi-layer stack, a plurality of memory cells, and a plurality of conductive contacts. The substrate includes an array region and a staircase region. The multi-layer stack is disposed on the substrate in the array region, wherein the multi-layer stack has an end portion extending on the staircase region to be shaped into a staircase structure. The plurality of memory cells are respectively disposed on sidewalls of the multi-layer stack in the array region, and arranged at least along a stacking direction of the multi-layer stack. The plurality of conductive contacts are respectively on the staircase structure. At least two conductive contacts are electrically connected to each other.

A device includes a first channel; a second channel above the first channel; and a gate structure surrounding the first and second channels, wherein the gate structure includes a ferroelectric (FE) layer surrounding the first and second channels and a gate metal layer surrounding the FE layer. The device further includes two first electrodes connected to two sides of the first channel; two second electrodes connected to two sides of the second channel; a dielectric layer between the first and the second electrodes; and an inner spacer layer between the two first electrodes and the gate structure.

A method of forming a ferroelectric random access memory (FeRAM) device includes: forming a first layer stack and a second layer stack successively over a substrate, where the first layer stack and the second layer stack have a same layered structure that includes a layer of a first electrically conductive material over a layer of a first dielectric material, where the first layer stack extends beyond lateral extents of the second layer stack; forming a trench that extends through the first layer stack and the second layer stack; lining sidewalls and a bottom of the trench with a ferroelectric material; conformally forming a channel material in the trench over the ferroelectric material; filling the trench with a second dielectric material; forming a first opening and a second opening in the second dielectric material; and filling the first opening and the second opening with a second electrically conductive material.

3D memory arrays including dummy conductive lines and methods of forming the same are disclosed. In an embodiment, a memory array includes a ferroelectric (FE) material over a semiconductor substrate, the FE material including vertical sidewalls in contact with a word line; an oxide semiconductor (OS) layer over the FE material, the OS layer contacting a source line and a bit line, the FE material being between the OS layer and the word line; a transistor including a portion of the FE material, a portion of the word line, a portion of the OS layer, a portion of the source line, and a portion of the bit line; and a first dummy word line between the transistor and the semiconductor substrate, the FE material further including first tapered sidewalls in contact with the first dummy word line.