A resistive random access memory (RRAM) and a method for operating the RRAM are disclosed. The RRAM includes at least two successively stacked conductive layers and a resistive switching layer situated between every adjacent two conductive layers, wherein a migration interface with an interface effect is formed at each interface between one conductive layer and the resistive switching layer in contact therewith, wherein the migration interface regulates, by the interface effect, vacancies formed in the resistive switching layer under the effect of an electrical signal. The regulation includes at least one of absorption, migration and diffusion.

Exemplary semiconductor structures for neuromorphic applications may include a first layer overlying a substrate material. The first layer may be or include a first oxide material. The structures may include a second layer disposed adjacent the first layer. The second layer may be or include a second oxide material. The structures may also include an electrode material deposited overlying the second layer.

A resistive memory device includes: conductive layers and interlayer insulating layers, which are alternatively stacked; a vertical hole vertically penetrating the conductive layers and the interlayer insulating layers; a gate insulating layer disposed over an inner wall of the vertical hole; a charge trap layer disposed over an inner wall of the gate insulating layer; a channel layer disposed over an inner wall of the charge trap layer; and a variable resistance layer disposed over an inner wall of the channel layer.

A transistor includes a first gate electrode, a composite channel layer, a first gate dielectric layer, and source/drain contacts. The composite channel layer is over the first gate electrode and includes a first capping layer, a crystalline semiconductor oxide layer, and a second capping layer stacked in sequential order. The first gate dielectric layer is located between the first gate electrode and the composite channel layer. The source/drain contacts are disposed on the composite channel layer.

A method of controlling the forming voltage of a dielectric film in a resistive random access memory (ReRAM) device. The method includes depositing a dielectric film contains intrinsic defects on a substrate, forming a plasma-excited treatment gas containing H.sub.2 gas, and exposing the dielectric film to the plasma-excited treatment gas to create additional defects in the dielectric film without substantially changing a physical thickness of the dielectric film, where the additional defects lower the forming voltage needed for generating an electrically conducting filament across the dielectric film. The dielectric film can include a metal oxide film and the plasma-excited treatment gas may be formed using a microwave plasma source.

A selector according to an embodiment of the present disclosure includes a first electrode; a second electrode disposed opposite to the first electrode; an ion supply layer disposed between the first electrode and the second electrode to be on the side of the first electrode and doped with a metal, wherein the doped metal diffuses toward the second electrode; a switching layer disposed between the first electrode and the second electrode to be on the side of the second electrode, wherein the doped metal diffuses from the ion supply layer into the switching layer so that metal concentration distribution inside the switching layer is changed to generate metal filaments; and a diffusion control layer inserted between the ion supply layer and the switching layer, wherein the diffusion control layer serves to adjust electrical characteristics related to the generated metal filaments as the amount of the diffusing metal is adjusted in proportion to a thickness of the diffusion control layer.

Various embodiments of the present application are directed towards a resistive random-access memory (RRAM) cell comprising a barrier layer to constrain the movement of metal cations during operation of the RRAM cell. In some embodiments, the RRAM cell further comprises a bottom electrode, a top electrode, a switching layer, and an active metal layer. The switching layer, the barrier layer, and the active metal layer are stacked between the bottom and top electrodes, and the barrier layer is between the switching and active metal layers. The barrier layer is conductive and between has a lattice constant less than that of the active metal layer.

A semiconductor memory device is provided. The memory device includes a first electrode, a resistive layer, and a second electrode. The resistive layer is arranged over the first electrode. The second electrode is arranged over the resistive layer. The second electrode includes a lower surface and an extension extending from under the lower surface. The extension is at least partially arranged within the resistive layer.

Various embodiments of the present disclosure are directed towards a memory cell comprising a high electron affinity dielectric layer at a bottom electrode. The high electron affinity dielectric layer is one of multiple different dielectric layers vertically stacked between the bottom electrode and a top electrode overlying the bottom electrode. Further, the high electrode electron affinity dielectric layer has a highest electron affinity amongst the multiple different dielectric layers and is closest to the bottom electrode. The different dielectric layers are different in terms of material systems and/or material compositions. It has been appreciated that by arranging the high electron affinity dielectric layer closest to the bottom electrode, the likelihood of the memory cell becoming stuck during cycling is reduced at least when the memory cell is RRAM. Hence, the likelihood of a hard reset/failure bit is reduced.

Disclosed are a method of operating a selector device, a method of operating a nonvolatile memory apparatus to which the selector device is applied, an electronic circuit device including the selector device, and a nonvolatile memory apparatus. The method of operating the selector device controls access to a memory element, and includes providing the selector device including a switching layer and first and second electrodes disposed on both surfaces of the switching layer, which includes an insulator and a metal element, and applying a multi-step voltage pulse to the switching layer via the first and second electrodes to adjust a threshold voltage of the selector device, the multi-step voltage pulse including a threshold voltage control pulse and an operating voltage pulse. The operating voltage pulse has a magnitude for turning on the selector device, and the threshold voltage control pulse has a lower magnitude lower than the operating voltage pulse.