A method includes forming a bottom electrode, forming a dielectric layer, forming a Phase-Change Random Access Memory (PCRAM) region in contact with the dielectric layer, and forming a top electrode. The dielectric layer and the PCRAM region are between the bottom electrode and the top electrode. A filament is formed in the dielectric layer. The filament is in contact with the dielectric layer.

A method for manufacturing a conductive bridging memory device includes the following steps. First, a bottom electrode is formed on a substrate. Next, a switching layer is formed on the bottom electrode. The switching layer is made of a semiconducting metal oxide and free of gallium. Then, a surface of the switching layer is subjected to an oxygen plasma surface treatment. Afterwards, a blocking layer including a conductive material is formed on the treated surface of the switching layer, and an upper electrode is formed on the blocking layer.

A memristor memory device comprises a memristive memory cell, an input terminal, an output terminal, and a gate terminal. The input terminal and the output terminal are directly attached to the memristive memory cell, and the gate terminal is electrically isolated from the memristive memory cell. The gate terminal is configured for receiving an electrical signal for a volatile modulation of a conductance of the memristive memory cell, by which a correction of non-ideal conductance modulations of the memristor memory device is achieved.

An array of vertically stacked tiers of memory cells includes a plurality of horizontally oriented access lines within individual tiers of memory cells and a plurality of horizontally oriented global sense lines elevationally outward of the tiers. A plurality of select transistors is elevationally inward of the tiers. A plurality of pairs of local first and second vertical lines extends through the tiers. The local first vertical line within individual of the pairs is in conductive connection with one of the global sense lines and in conductive connection with one of the two source/drain regions of one of the select transistors. The local second vertical line within individual of the pairs is in conductive connection with another of the two source/drain regions of the one select transistor. Individual of the memory cells include a crossing one of the local second vertical lines and one of the horizontal access lines and programmable material there-between. Other aspects and implementations, including methods, are disclosed.

Memory devices and memory operational methods are described. One example memory system includes a common conductor and a plurality of memory cells coupled with the common conductor. The memory system additionally includes access circuitry configured to provide different ones of the memory cells into one of a plurality of different memory states at a plurality of different moments in time between first and second moments in time. The access circuitry is further configured to maintain the common conductor at a voltage potential, which corresponds to the one memory state, between the first and second moments in time to provide the memory cells into the one memory state.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a first resistive random access memory (RRAM) element over a substrate. The first RRAM element has a first terminal and a second terminal. A second RRAM element is arranged over the substrate and has a third terminal and a fourth terminal. The third terminal is electrically coupled to the first terminal of the first RRAM element. A reading circuit is coupled to the second terminal and the fourth terminal. The reading circuit is configured to read a single data state from both a first non-zero read current received from the first RRAM element and a second non-zero read current received from the second RRAM element.

A semiconductor channel based neuromorphic synapse device 1 including a trap-rich layer may be provided that includes: a first to a third semiconductor regions which are formed on a substrate and are sequentially arranged; a word line which is electrically connected to the first semiconductor region; a trap-rich layer which surrounds the second semiconductor region; and a bit line which is electrically connected to the third semiconductor region. When a pulse with positive (+) voltage is applied to the word line, a concentration of electrons emitted from the trap-rich layer to the second semiconductor region increases and a resistance of the second semiconductor region decreases. When a pulse with negative (−) voltage is applied to the word line, a concentration of electrons trapped in the trap-rich layer from the second semiconductor region increases and the resistance of the second semiconductor region increases.

A method for manufacturing a semiconductor memory device includes depositing a bottom metal line layer on a dielectric layer, and patterning the bottom metal line layer into a plurality of bottom metal lines spaced apart from each other. In the method, a plurality of switching element dielectric portions are formed on respective ones of the plurality of bottom metal lines, and a top metal line layer is deposited on the plurality of switching element dielectric portions. The method further includes patterning the top metal line layer into a plurality of top metal lines spaced apart from each other. The plurality of top metal lines are oriented perpendicular to the plurality of bottom metal lines.

A nonvolatile memory device includes a substrate having an upper surface and a channel structure disposed over the substrate. The channel structure includes at least one channel layer pattern and at least one interlayer insulation layer pattern, which are alternately stacked in a first direction perpendicular to the upper surface, and the channel structure extends in a second direction perpendicular to the first direction. The nonvolatile memory device includes a resistance change layer disposed over the substrate and on at least a portion of one sidewall surface of the channel structure, a gate insulation layer disposed over the substrate and on the resistance change layer, and a plurality of gate line structures disposed over the substrate, each contacting a first surface of the gate insulation layer and disposed to be spaced apart from each other in the second direction.

An resistive switch having a first platinum layer, an electrolyte layer that is formed by extrusion based additive manufacturing, a silver layer, and a second platinum layer, and methods of manufacturing and using the resistive switch.