According to an embodiment, a phase-change memory device comprises: an upper electrode and a lower electrode; a phase-change layer in which a crystal state thereof is changed by heat supplied by the upper electrode and the lower electrode; and a selector which selectively switches the heat supplied by the upper electrode and the lower electrode to the phase-change layer, wherein the selector is formed of a compound which includes a transition metal in the phase-change material so as to have a high resistance when the crystalline state of the selector is crystalline and so as to have a low resistance when the crystalline state of the selector is non-crystalline.

A phase change memory device includes a bottom conductive line, a dielectric layer, a bottom memory layer, and a top electrode. The dielectric layer covers the bottom conductive line. The bottom memory layer is in the dielectric layer and is electrically connected to the bottom conductive line. The bottom memory layer includes a tapered portion and a neck portion. The tapered portion is over the bottom conductive line and is tapered toward the bottom conductive line. The neck portion is directly between the tapered portion and the bottom conductive line. The neck portion has a substantially constant width. The top electrode is over and electrically connected to the bottom memory layer.

A memory cell including a two-terminal re-writeable non-volatile memory element having at least two layers of conductive metal oxide (CMO), which, in turn, can include a first layer of CMO including mobile oxygen ions, and a second layer of CMO formed in contact with the first layer of CMO to cooperate with the first layer of CMO to form an ion obstruction barrier. The ion obstruction barrier is configured to inhibit transport or diffusion of a subset of mobile ion to enhance, among other things, memory effects and cycling endurance of memory cells. At least one layer of an insulating metal oxide that is an electrolyte to the mobile oxygen ions and configured as a tunnel barrier is formed in contact with the second layer of CMO.

A method of manufacturing a memory device includes sequentially forming and then etching a preliminary selection device layer, a preliminary middle electrode layer, and a preliminary variable resistance layer on a substrate, thereby forming a selection device, a middle electrode, and a variable resistance layer. At least one of a side portion of the selection device or a side portion of the variable resistance layer is removed so that a first width of the middle electrode in a first direction parallel to a top of the substrate is greater than a second width of the variable resistance layer in the first direction or a third width of the selection device in the first direction. A capping layer is formed on at least one of a side wall of the etched side portion of the selection device or a side wall of the etched side portion of the variable resistance layer.

A memory device includes a substrate, an electrical channel layer, a first electrode, a resistive switching layer, a second electrode, and a conductive structure. The electrical channel layer is disposed on the substrate. The first electrode is disposed on the substrate and extends into the electrical channel layer. The resistive switching layer is disposed between the first electrode and the electrical channel layer. The second electrode is disposed on the electrical channel layer. The conductive structure connects the electrical channel layer and the second electrode.

Methods, systems, and devices for a resistive interface material are described. A memory device may be fabricated using a sequence of steps that include forming a stack of materials by depositing a first metal layer, depositing a first electrode layer on the metal layer, depositing a memory material on the first electrode layer to form one or more memory cells, depositing a second electrode layer on the memory material, and depositing a second metal layer on the second electrode layer. A lamina (or multiple) having a relatively high resistivity may be included in the stack of materials to reduce or eliminate a current spike that may otherwise occur across the memory cells during an access operation.

A system may include an array of interconnected memristors. Each memristor may include a first electrode, a second electrode, and a memristor material positioned between the first electrode and the second electrode. The system may further include a controller communicatively coupled to the array of interconnected memristors. The controller may be configured to tune the array of interconnected memristors.

A cross-point memory array and stacked memory array structure. The memory array includes a plurality of first conductive line structures formed in a dielectric material layer; a plurality of memory elements, each memory element including a fill-in phase change memory (PCM) cell, and an access device enabling read or write access to said memory PCM structure; a plurality of second conductive line structures, the plurality of second conductive structures perpendicularly oriented relative to the plurality of first conductive structures. An individual memory element of the plurality of memory elements is conductively connected at a respective intersection between a first conductive line structure and a second conductive line structure. Each phase change memory (PCM) cell of a memory element at an intersection having a sub-lithographic conductive tuning liner disposed on only one sidewall of the PCM cell. The manufacturing maintains a minimal number of masking and processing steps.

Technologies relating to RRAM crossbar array circuits with specialized interface layers for the low current operations are disclosed. An example apparatus includes: a substrate; a bottom electrode formed on the substrate; a first layer formed on the bottom electrode; an RRAM oxide layer formed on the first layer and the bottom electrode; and a top electrode formed on the RRAM oxide layer. The first layer may be a continuous layer or a discontinuous layer. The apparatus may further comprise a second layer formed between the RRAM oxide layer and the top electrode. The second layer may be a continuous layer or a discontinuous layer.

A phase change memory device comprising, between first and second electrodes: a first layer of a phase change material; and a second germanium nitride-based layer, in contact with the first layer, the nitrogen percentage in the second layer being between 20% and 35%, and the second layer having a channel of the phase change material of the first layer passing through it.