Embodiments relate to a semiconductor structure, a memory structure and fabrication methods thereof. The semiconductor structure includes: a substrate, where a spacer is provided on the substrate, and a bit line structure is provided in the spacer and is at least partially exposed to the spacer; active area structures, where each of the active area structures includes an active pillar and a stress layer, the active pillar is positioned on the bit line structure, and the stress layer covers an exposed surface of the active pillar; each of the active area structure includes a first connection terminal, a second connection terminal, and a channel region positioned between the first connection terminal and the second connection terminal, and the first connection terminal is electrically connected to the bit line structure; and a word line structure covering a periphery of the channel region.

Embodiments of the present disclosure provide power to backend memory of an IC device from the back side of the device. An example IC device with back-side power delivery for backend memory includes a frontend layer with a plurality of frontend components such as frontend transistors, a backend layer (that may include a plurality of layers) with backend memory (e.g., with one or more eDRAM arrays), and a back-side power delivery structure with a plurality of back-side interconnects electrically coupled to the backend memory, where the frontend layer is between the back-side power delivery structure and the backend layer.

Provided is a step of forming, on a P-layer substrate 20, an N.sup.+ layer 21A to be connected to a source line SL, Si pillars 25a to 25d, N.sup.+ layers 23A to 23D to be connected to bit lines BL1 and BL2, HfO.sub.2 layers 30a and 32 surrounding lower and upper portions of the Si pillars 25a to 25d, a TiN layer 31a to be connected to a plate line PL, and TiN layers 33a and 33b to be connected to word lines WL1 and WL2. P layers 27a to 27d are formed so as to surround the Si pillars 25a to 25d and so as to be deposited on them to form a plurality of dynamic flash memory cells arranged in rows and columns.

Integrated circuit (IC) devices with stacked two-level backend memory, and associated systems and methods, are disclosed. An example IC device includes a front end of line (FEOL) layer, including frontend transistors, and a back end of line (BEOL) layer above the FEOL layer. The BEOL layer includes a first memory layer with memory cells of a first type, and a second memory layer with memory cells of a second type. The first memory layer may be between the FEOL layer and the second memory layer, thus forming stacked backend memory. Stacked backend memory architecture may allow significantly increasing density of memory cells in a memory array having a given footprint area, or, conversely, reducing the footprint area of the memory array with a given memory cell density. Implementing two different types of backend memory may advantageously increase functionality and performance of backend memory.

IC devices with backend memory and electrical feedthrough networks of interconnects between the opposite sides of the IC devices, and associated assemblies, packages, and methods, are disclosed. An example IC device includes a back-side interconnect structure, comprising back-side interconnects; a frontend layer, comprising frontend transistors; a backend layer, comprising backend memory cells and backend interconnects; and a front-side interconnect structure, comprising front-side interconnects. In such an IC device, the frontend layer is between the back-side interconnect structure and the backend layer, the backend layer is between the frontend layer and the front-side interconnect structure, and at least one of the back-side interconnects is electrically coupled to at least one of the front-side interconnects by an electrical feedthrough network of two or more of the backend interconnects.

Disclosed herein are memory cells and memory arrays, as well as related methods and devices. For example, in some embodiments, a memory device may include: a support having a surface; and a three-dimensional array of memory cells on the surface of the support, wherein individual memory cells include a transistor and a capacitor, and a channel of the transistor in an individual memory cell is oriented parallel to the surface.

The invention discloses a dynamic random access memory (DRAM) device and a method of fabricating such DRAM device. The DRAM device according to the invention includes a plurality of bit lines formed on a semiconductor substrate, a plurality of first isolation stripes, a plurality of second isolation stripes, a plurality of transistors formed between the first isolation stripes and the second isolation stripes, a plurality of word lines, and a plurality of capacitors formed above the first isolation stripes and the second isolation stripes. The semiconductor substrate defines a longitudinal direction, a transverse direction, a normal direction, a plurality of columns in the longitudinal direction, and a plurality of rows in the transverse direction. The first isolation stripes and the second isolation stripes extend in the longitudinal direction. Each transistor corresponds to one of the columns and one of the rows. The transistors on one side of each first isolation stripe and the transistors on the other side of said one first isolation stripe are staggeredly arranged. Each word line corresponds to one of the columns and connects the gate conductors of the transistors along the corresponding column. Each capacitor corresponds to one of the transistors and connects the source region of the corresponding transistor.

An example IC device includes a frontend layer and a backend layer with a metallization stack. The metallization stack includes a backend memory layer with a plurality of memory cells with backend transistors, and a layer with a plurality of conductive interconnects (e.g., a plurality of conductive lines) and air gaps between adjacent ones of the plurality of interconnects. Providing air gaps in upper metal layers of metallization stacks of IC devices may advantageously reduce parasitic effects in the IC devices because such effects are typically proportional to the dielectric constant of a surrounding medium. In turn, reduction in the parasitic effects may lead to improvements in performance of, or requirements placed on, the backend memory.

Embodiments of the present disclosure provide a side-channel dynamic random access memory (DRAM) cell and cell array that utilizes a vertical design with side channel transistors. A dielectric layer disposed over a substrate. A gate electrode is embedded in the dielectric layer. A channel layer wraps the gate electrode and a conductive structure is adjacent to the channel layer, with the channel layer interposed between the gate electrode and the conductive structure. The semiconductor structure also includes a dielectric structure disposed over the conductive structure and the gate electrode, the channel layer extending up through the dielectric structure.

Provided is a semiconductor device, including an insulating layer, a transistor located on the insulating layer, and a conductive structure, in which the transistor includes: a source, a channel and a drain arranged in parallel, as well as a gate dielectric layer and a gate structure, in which the gate dielectric layer is located between the gate structure and the channel; the conductive structure covers one sidewall of the channel and is used for grounding; the gate structure is disposed around the other three sidewalls of the channel; and the gate structure and the conductive structure are isolated from each other.