A resistive memory device is provided. The resistive memory device comprises a first electrode and a resistive layer over the first electrode, the resistive layer having a sidewall. A second electrode is over the resistive layer. An insulating liner is formed on the sidewall of the resistive layer. The insulating liner comprises two layers of different dielectric materials.

A storage device includes a first electrode, a second electrode, and a resistance change storage layer between the first and second electrodes. The storage layer is either in a first resistance state or in a second resistance state having a resistance higher than the first resistance state and contains at least two elements selected from a group consisting of germanium, antimony, and tellurium. The storage device further includes an interface layer between the first electrode and the resistance change storage layer. The interface layer contains at least one of the elements of the resistance change storage layer and includes a conductive region and an insulating region.

In one embodiment, a method of manufacturing a semiconductor device includes forming a first layer including a metal element on a substrate, and processing the first layer by dry etching. The method further includes removing a second layer formed on a lateral face of the first layer by wet etching, after processing the first layer, and forming a first film on the lateral face of the first layer by processing the lateral face of the first layer with a liquid, after removing the second layer. Furthermore, the substrate is not exposed to ambient air, after removing the second layer and before forming the first film.

A method for forming a nonvolatile PCM logic device may include providing a PCM film component having a first end contact distally opposed from a second end contact, positing a first proximity adjacent to a first surface of the PCM film component, positing a second proximity heater adjacent to a second surface of the PCM film component, wherein the first proximity heater and the second proximity heater are electrically isolated from the PCM film component. The method may further include applying a combination of pulses to one or more of the first proximity heater and the second proximity heater to change a resistance value of the PCM film component corresponding to a logic truth table. Further, the method may include simultaneously applying a first combination of reset pulses to program, or set pulses to initialize, the PCM film component, to the first proximity heater and the second proximity heater.

A memory device may include a first conductor and a second conductor; a switching layer arranged between the first conductor and the second conductor, and one or more magnetic layers. The switching layer may be configured to have a switchable resistance in response to a change in voltage between the first conductor and the second conductor. The one or more magnetic layers may be arranged such that the one or more magnetic layers provide a magnetic field through the switching layer.

The disclosed technology relates generally to integrated circuit devices, and in particular to cross-point memory arrays and methods for fabricating the same. In one aspect, a method of fabricating cross-point memory arrays comprises forming a memory cell material stack which includes a first active material and a second active material over the first active material, wherein one of the first and second active materials comprises a storage material and the other of the first and second active materials comprises a selector material. The method of fabricating cross-point arrays further comprises patterning the memory cell material stack, which includes etching through at least one of the first and second active materials of the memory cell material stack, forming protective liners on sidewalls of the at least one of the first and second active materials after etching through the one of the first and second active materials, and further etching the memory cell material stack after forming the protective liners on the sidewalls of the one of the first and second active materials.

The present disclosure, in some embodiments, relates to a resistive random access memory (RRAM) cell. The RRAM cell has a bottom electrode over a substrate. A data storage layer is over the bottom electrode and has a first thickness. A capping layer is over the data storage layer. The capping layer has a second thickness that is in a range of between approximately 1.9 and approximately 3 times thicker than the first thickness. A top electrode is over the capping layer.

A semiconductor device includes a diffusion barrier structure, a bottom electrode, a top electrode over the bottom electrode, a switching layer and a capping layer. The bottom electrode is over the diffusion barrier structure. The top electrode is over the bottom electrode. The switching layer is between the bottom electrode and the top electrode, and configured to store data. The capping layer is between the top electrode and the switching layer. A thermal conductivity of the diffusion barrier structure is greater than approximately 20 W/mK.

A semiconductor memory structure includes a memory cell, an encapsulation layer over a sidewall of the memory cell, and a nucleation layer between the sidewall of the memory cell and the encapsulation layer. The memory cell includes a top electrode, a bottom electrode and a data-storage element sandwiched between the bottom electrode and the top electrode. The nucleation layer includes metal oxide.

A semiconductor device includes a diffusion barrier structure, a bottom electrode, a top electrode, a switching layer and a capping layer. The bottom electrode is over the diffusion barrier structure. The top electrode is over the bottom electrode. The switching layer is between the bottom electrode and the top electrode, and configured to store data. The capping layer is between the switching layer and the top electrode. The diffusion barrier structure includes a multiple-layer structure. A thermal conductivity of the diffusion barrier structure is greater than approximately 20 W/mK.