A 3-dimensional vertical memory string array includes high-speed ferroelectric field-effect transistor (FET) cells that are low-cost, low-power, or high-density and suitable for SCM applications. The memory circuits of the present invention provide random-access capabilities. The memory string may be formed above a planar surface of substrate and include a vertical gate electrode extending lengthwise along a vertical direction relative to the planar surface and may include (i) a ferroelectric layer over the gate electrode, (ii) a gate oxide layer; (iii) a channel layer provided over the gate oxide layer; and (iv) conductive semiconductor regions embedded in and isolated from each other by an oxide layer, wherein the gate electrode, the ferroelectric layer, the gate oxide layer, the channel layer and each adjacent pair of semiconductor regions from a storage transistor of the memory string, and wherein the adjacent pair of semiconductor regions serve as source and drain regions of the storage transistor.

A 3-dimensional vertical memory string array includes high-speed ferroelectric field-effect transistor (FET) cells that are low-cost, low-power, or high-density and suitable for SCM applications. The memory circuits of the present invention provide random-access capabilities. The memory string may be formed above a planar surface of substrate and include a vertical gate electrode extending lengthwise along a vertical direction relative to the planar surface and may include (i) a ferroelectric layer over the gate electrode, (ii) a gate oxide layer; (iii) a channel layer provided over the gate oxide layer, and (iv) conductive semiconductor regions embedded in and isolated from each other by an oxide layer, wherein the gate electrode, the ferroelectric layer, the gate oxide layer, the channel layer and each adjacent pair of semiconductor regions from a storage transistor of the memory string, and wherein the adjacent pair of semiconductor regions serve as source and drain regions of the storage transistor.

A 3-dimensional vertical memory string array includes high-speed ferroelectric field-effect transistor (FET) cells that are low-cost, low-power, or high-density and suitable for SCM applications. The memory circuits of the present invention provide random-access capabilities. The memory string may be formed above a planar surface of substrate and include a vertical gate electrode extending lengthwise along a vertical direction relative to the planar surface and may include (i) a ferroelectric layer over the gate electrode, (ii) a gate oxide layer; (iii) a channel layer provided over the gate oxide layer; and (iv) conductive semiconductor regions embedded in and isolated from each other by an oxide layer, wherein the gate electrode, the ferroelectric layer, the gate oxide layer, the channel layer and each adjacent pair of semiconductor regions from a storage transistor of the memory string, and wherein the adjacent pair of semiconductor regions serve as source and drain regions of the storage transistor.

Embodiments of a semiconductor memory device include a substrate having a first region with peripheral devices, a second region with one or more memory arrays, and a third region between the first and the second regions. The semiconductor memory device also includes a protective structure for peripheral devices. The protective structure for peripheral devices of the semiconductor memory device includes a first dielectric layer and a barrier layer disposed on the first dielectric layer. The protective structure for peripheral devices of the semiconductor memory device further includes a dielectric spacer formed on a sidewall of the barrier layer and a sidewall of the first dielectric layer, wherein the protective structure is disposed over the first region and at least a portion of the third region.

Embodiments of a semiconductor memory device include a substrate having a first region with peripheral devices, a second region with one or more memory arrays, and a third region between the first and the second regions. The semiconductor memory device also includes a protective structure for peripheral devices. The protective structure for peripheral devices of the semiconductor memory device includes a first dielectric layer and a barrier layer disposed on the first dielectric layer. The protective structure for peripheral devices of the semiconductor memory device further includes a dielectric spacer formed on a sidewall of the barrier layer and a sidewall of the first dielectric layer, wherein the protective structure is disposed over the first region and at least a portion of the third region.

Apparatuses and techniques for fast programming and read operations for memory cells. A group of word lines comprising a selected word line and one or more adjacent word lines are driven with a common voltage signal during program and read operations. The word lines may be permanently connected to one another or connected by a switch. In another approach, the word lines are driven separately by common voltage signals. In a set of blocks, one block of memory cells can be provided with connected word lines to provide a relatively high access speed, while another block of memory cells has disconnected word lines to provide a higher storage density. In another aspect, the memory cells of a word line are divided into portions, and a portion which is closest to a row decoder is reserved for high access speed with a low storage density.

A memory device may include first and second pillar-shaped active regions formed on a substrate and extending upward. The first and second active regions are arranged in a first array and a second array, respectively. Each of the first active regions comprises alternatively stacked source/drain layers and channel layers, wherein the channel layers of the respective first active regions at a corresponding level are substantially coplanar with each other, and the source/drain layers of the respective first active regions at a corresponding level are substantially coplanar with each other. Each of the second active regions comprises an active semiconductor layer extending integrally. The memory device may include multiple layers of first storage gate stacks surrounding peripheries of and being substantially coplanar with the respective levels of the channel layers, and multiple layers of second storage gate stacks which surround peripheries of the respective second active regions.

In some embodiments, the present disclosure relates to an integrated circuit. The integrated circuit has a first doped region and a second doped region within a substrate. A FeRAM (ferroelectric random access memory) device is arranged over the substrate between the first doped region and the second doped region. The FeRAM device has a ferroelectric material and a conductive electrode. The ferroelectric material is arranged over the substrate and the conductive electrode is arranged over the ferroelectric material and between sidewalls of the ferroelectric material.

A test structure for 3D memory arrays and methods of forming the same are disclosed. In an embodiment, a memory array includes a first word line over a semiconductor substrate and extending in a first direction; a second word line over the first word line and extending in the first direction; a memory film contacting the first word line and the second word line; an oxide semiconductor (OS) layer contacting a first source line and a first bit line, the memory film being between the OS layer and each of the first word line and the second word line; and a test structure over the first word line and the second word line, the test structure including a first conductive line electrically coupling the first word line to the second word line, the first conductive line extending in the first direction.

An integrated circuit is provided. The integrated circuit includes a three-dimensional memory device, a first word line driving circuit and a second word line driving circuit. The three-dimensional memory device includes stacking structures separately extending along a column direction. Each stacking structure includes a stack of word lines. The stacking structures have first staircase structures at a first side and second staircase structures at a second side. The word lines extend to steps of the first and second staircase structures. The first and second word line driving circuits lie below the three-dimensional memory device, and extend along the first and second sides, respectively. Some of the word lines in each stacking structure are routed to the first word line driving circuit from a first staircase structure, and others of the word lines in each stacking structure are routed to the second word line driving circuit from a second staircase structure.