A device for selecting a storage cell, includes a first electrode, a second electrode and an oxide layer disposed between the first electrode and the second electrode, wherein the oxide layer is doped with a first element from column IV of the periodic table.

Methods, systems, and devices for memory arrays having graded memory stack resistances are described. An apparatus may include a first subset of memory stacks having a first resistance based on a physical and/or electrical distance of the first subset of memory stacks from at least one of a first driver component or a second driver component. The apparatus may include a second subset of memory stacks having a second resistance that is less than the first resistance based on a physical and/or electrical distance of the second subset of memory from at least one of the first driver component or the second driver component.

Methods and devices based on the use of dopant-modulated etching are described. During fabrication, a memory storage element of a memory cell may be non-uniformly doped with a dopant that affects a subsequent etching rate of the memory storage element. After etching, the memory storage element may have an asymmetric geometry or taper profile corresponding to the non-uniform doping concentration. A multi-deck memory device may also be formed using dopant-modulated etching. Memory storage elements on different memory decks may have different taper profiles and different doping gradients.

A method of forming a resistive random access memory cell includes the following steps. A first electrode layer, a blanket resistive switching material layer and a second electrode layer are formed on a layer sequentially. The second electrode layer is patterned to form a second electrode. The blanket resistive switching material layer is patterned to form a resistive switching material layer. An oxygen implanting process is performed to implant oxygen in two sidewall parts of the resistive switching material layer.

Subject matter disclosed herein may relate to fabrication of a correlated electron material (CEM) such as in a CEM device capable of switching between and/or among impedance states. In particular embodiments, a CEM may be formed from one or more transition metal oxides (TMOs), one or more post transition metal oxides (PTMOs) or one or more post transition metal chalcogenides (PTMCs), or a combination thereof.

A phase change memory cell is provided that includes a phase change material-containing structure sandwiched between first and second electrodes. The phase change material-containing structure has a resistance that changes gradually, and thus may be used in analog or neuromorphic computing. The phase change material-containing structure may contain a plurality of phase change material pillars, wherein each phase change material pillar has a different phase change material composition. Alternatively, the phase change material-containing structure may contain a doped phase change material layer in which a dopant concentration decreases laterally inward from an outermost surface thereof.

Provided is a non-volatile memory including a conductor layer, a memory device, and a selector. The selector is located between and electrically connected to the memory device and the conductive layer. The selector includes a metal filling layer, a barrier layer, and a rectify layer. The metal filling layer is electrically connected to the memory device. The barrier layer is located on the sidewall and the bottom surface of the metal filling layer. The rectify layer is wrapped around the barrier layer. The rectify layer includes a first portion and a second portion. The first portion is located between the barrier layer on the bottom surface of the metal filling layer and the conductive layer. The second portion and the metal filling layer sandwich the barrier layer on the sidewall of the metal filling layer. The first portion has more diffusion paths of metal ions than the second portion.

According to one embodiment, a nonvolatile memory device includes a first wiring extending in a first direction, a second wiring extending in a second direction, a third wiring extending in the second direction and spaced from the second wiring in the first direction. An insulating layer includes a first portion between the second wiring and the third wiring, and a second portion protruding from the first portion in a third direction. A chalcogenide layer is between the first wiring and the second wiring, the first wiring and the third wiring, and also the first wiring and the insulating layer. The chalcogenide layer includes a first layer portion, a second layer portion, and a third layer portion. A concentration of a first element in the third layer portion is higher than that in the first and second layer portions.

Methods, systems, and devices for memory arrays having graded memory stack resistances are described. An apparatus may include a first subset of memory stacks having a first resistance based on a physical and/or electrical distance of the first subset of memory stacks from at least one of a first driver component or a second driver component. The apparatus may include a second subset of memory stacks having a second resistance that is less than the first resistance based on a physical and/or electrical distance of the second subset of memory from at least one of the first driver component or the second driver component.

An RRAM structure and its manufacturing method are provided. The RRAM structure includes a bottom electrode layer, a resistance switching layer, and an implantation control layer sequentially formed on a substrate. The resistance switching layer includes a conductive filament confined region and an outer region surrounding the conductive filament confined region. The RRAM structure includes a protective layer and a top electrode layer. The protective layer conformally covers the bottom electrode layer, the resistance switching layer, and the implantation control layer and has a first opening. The top electrode layer is located on the implantation control layer, and a portion of the top electrode layer is filled into the first opening. The position of the top electrode layer corresponds to that of the conductive filament confined region, and the top surface of the top electrode layer is higher than that of the protective layer.