The present invention disclosures a memory array structure, comprising an array composed of multiple memory devices arranged in rows and columns, each of the rows is set with a row leading-out wire, and each of the columns is set with a column leading-out wire, memory devices are correspondingly positioned at intersection points of each row leading-out wire and each column leading-out wire; wherein, the first terminal of each of the memory devices is individually connected to the row leading-out wire of the same row, and the second terminal of each of the memory devices is connected to a first terminal of a switch in the same column, the second terminal of the switch is connected to the column leading-out wire of the same column; wherein, each of the rows is set with one to multiple the switches, and the first terminal of each of the switches is connected to one to all of the second terminals of the memory devices in the same column. The advantage of the present invention is that the corresponding analog currents output of input signals of different specified rows according to multiply-accumulate operation requirements of each of the columns can be obtained simultaneously, thus multiply-accumulate operations of different input signals of different scales can be performed, which greatly improves operation speed and using efficiency of the array.

A phase-change memory cell includes a heater, a memory region made of a phase-change material located above said heater, and an electrically conductive element positioned adjacent to the memory region and the heater at a first side of the heater. The electrically conductive element extends parallel to a first axis and has, parallel to the first axis, a first dimension at the first side that is greater than a second dimension at a second side opposite to the first side.

Methods, systems, and devices for a decoding architecture for memory devices are described. Word line plates of a memory array may each include a sheet of conductive material that includes a first portion extending in a first direction within a plane along with multiple fingers extending in a second direction within the plane. Two word line plates in a same plane may be activated via a shared electrode. Memory cells coupled with the two word line plates sharing the electrode, or a subset thereof, may represent a logical page for accessing memory cells. A memory cell may be accessed via a first voltage applied to a word line plate coupled with the memory cell and a second voltage applied to a pillar electrode coupled with the memory cell. Parallel or simultaneous access operations may be performed for two or more memory cells within a same page of memory cells.

A method includes forming a transistor having source and drain regions. The following are formed on the source/drain region: a first via, a first metal layer extending along a first direction on the first via, a second via overlapping the first via on the first metal layer, and a second metal extending along a second direction different from the first direction on the second via; and the following are formed on the drain/source region: a third via, a third metal layer on the third via, a fourth via overlapping the third via over the third metal layer, and a controlled device at a same height level as the second metal layer on the third metal layer.

Various embodiments of the present application are directed towards a resistive random-access memory (RRAM) cell including a top-electrode barrier layer configured to block the movement of nitrogen or some other suitable non-metal element from a top electrode of the RRAM cell to an active metal layer of the RRAM cell. Blocking the movement of non-metal element may be prevent formation of an undesired switching layer between the active metal layer and the top electrode. The undesired switching layer would increase parasitic resistance of the RRAM cell, such that top-electrode barrier layer may reduce parasitic resistance by preventing formation of the undesired switching layer.

Row and/or column electrode lines for a memory device are staggered such that gaps are formed between terminated lines. Vertical interconnection to central points along adjacent lines that are not terminated are made in the gap, and vertical interconnection through can additionally be made through the gap without contacting the lines of that level.

A multi-bit resistive random access memory cell includes a plurality of bottom electrodes, a plurality of dielectric layers, a top electrode and a resistance layer. The bottom electrodes and the dielectric layers are interleaved layers, each of the bottom electrodes is sandwiched by the dielectric layers, and a through hole penetrates through the interleaved layers. The top electrode is disposed in the through hole. The resistance layer is disposed on a sidewall of the through hole and is between the top electrode and the interleaved layers, thereby the top electrode, the resistance layer and the bottom electrodes constituting a multi-bit resistive random access memory cell. The present invention also provides a method of forming the multi-bit resistive random access memory cell.

A semiconductor memory device includes a substrate and a transistor disposed on the substrate. The transistor includes a source doped region, a drain doped region, a channel region, and a gate over the channel region. A data storage region is in proximity to the transistor and recessed into the substrate. The data storage region includes a ridge and a V-shaped groove. A bottom electrode layer conformally covers the ridge and V-shaped groove within the data storage region. A resistive-switching layer conformally covers the bottom electrode layer. A top electrode layer covers the resistive-switching layer.

The present invention discloses a method for manufacturing a phase change memory and a phase change memory. The method comprises: forming a first wafer having a semiconductor-on-insulator structure; forming a memory material layer on the semiconductor-on-insulator structure; and forming a first metal material layer on the memory material layer to form a first semiconductor element.

In fabrication of a phase change random access memory (PCRAM), a field effect transistor (FET) logic layer is formed on a first wafer, including a heating FET for each storage cell. The FET logic layer is transferred from the first wafer to a carrier wafer. Thereafter, a storage layer of the PCRAM is formed on the exposed surface of the FET logic layer, including a region of a phase change material for each storage cell that is electrically connected to a channel of the heating FET of the storage cell. The storage layer further includes a second heating transistor for each storage cell that is electrically connected to a channel of the second heating transistor.