Disclosed in Disclosed are a resistive random access memory and a manufacturing method. A memory area of the resistive random access memory comprises a first metal interconnection line, a resistive random access memory unit and a second metal interconnection line that are connected in sequence, wherein the whole or part of a bottom electrode of the resistive random access memory unit is arranged in a short through hole of a barrier layer on the first metal interconnection line; the first metal interconnection line is connected to the bottom electrode of the resistive random access memory unit; and the second metal interconnection line is connected to a top electrode of the resistive random access memory unit. By means of arranging the whole or part of the bottom electrode of the resistive random access memory unit in the short through hole of the barrier layer on the first metal interconnection line, the bottom electrode can be made to be very thin, such that the height of the resistive random access memory unit in a CMOS back end of line is reduced, the thickness, which needs to be occupied, of each layer in the CMOS back end of line is smaller, integration is facilitated, the back end of line of a logic circuit area cannot be influenced, and the total stacking thickness can meet the electrical property requirement of the resistive random access memory. The process integration scheme in the embodiments of the present application can make the integration of an RRAM and a standard CMOS simpler.

A semiconductor structure may include a resistive random access memory device embedded between an upper metal interconnect and a lower metal interconnect in a backend structure of a chip. The resistive random access memory may include a first electrode and a second electrode separated by a dielectric film. A portion of the dielectric film directly above the first electrode may be crystalline. The semiconductor structure may include a stud below and in electrical contact with the first electrode and the lower metal interconnect and a dielectric layer between the upper metal interconnect and the lower metal interconnect. The dielectric layer may separate the upper metal interconnect from the lower metal interconnect. The crystalline portion of the dielectric film may include grain boundaries that extend through an entire thickness of the dielectric film. The crystalline portion of the dielectric film may include grains.

A memory device includes at least one bit line, at least one word line, and at least one memory cell. The memory cell includes a first transistor, a plurality of data storage elements, and a plurality of second transistors corresponding to the plurality of data storage elements. The first transistor includes a gate electrically coupled to the word line, a first source/drain, and a second source/drain. Each data storage element among the plurality of data storage elements and the corresponding second transistor are electrically coupled in series between the first source/drain of the first transistor and the bit line.

A memory device includes a stack and a plurality of memory strings. The stack is disposed on the substrate, and the stack includes a plurality of conductive layers and a plurality of insulating layers alternately stacked. The memory strings pass through the stack along a first direction, wherein a first memory string in the memory strings includes a first conductive pillar and a second conductive pillar, a channel layer, and a memory structure. The first conductive pillar and the second conductive pillar respectively extend along the first direction and are separated from each other. The channel layer is disposed between the first conductive pillar and the second conductive pillar. The memory structure surrounds the second conductive pillar, and the memory structure includes a resistive memory material.

Embodiments of the present application relate to a resistive memory device and a preparation method thereof. The preparation method includes: providing a base; forming bit line trenches in the base; forming a resistive material layer on a sidewall and the bottom of the bit line trench; and forming a bit line structure in the bit line trench through filling, wherein a variable resistor structure includes the bit line structure and the resistive material 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.

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 and a method of manufacturing the semiconductor memory device are provided. The semiconductor memory device includes a plurality of insulating layers spaced apart from each other in a stacking direction, a slit insulating layer passing through the plurality of insulating layers, a plurality of first variable resistance layers alternately disposed with the plurality of insulating layers in the stacking direction, a plurality of conductive lines interposed between the slit insulating layer and the plurality of first variable resistance layers and alternately disposed with the plurality of insulating layers in the stacking direction, a conductive pillar passing through the plurality of insulating layers and the plurality of first variable resistance layers, and a second variable resistance layer surrounding a sidewall of the conductive pillar.

A resistive memory device includes a bottom electrode, a top electrode and a resistance changing element. The top electrode is disposed above and spaced apart from the bottom electrode, and has a downward protrusion aligned with the bottom electrode. The resistance changing element covers side and bottom surfaces of the downward protrusion.

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.