A vertical variable resistance memory device includes gate electrodes and a pillar structure. The gate electrodes are spaced apart from one another on a substrate in a vertical direction substantially perpendicular to an upper surface of the substrate. The pillar structure extends in the vertical direction through the gate electrodes on the substrate. The pillar structure includes a vertical gate electrode extending in the vertical direction, a variable resistance pattern disposed on a sidewall of the vertical gate electrode, and a channel disposed on an outer sidewall of the variable resistance pattern. The channel and the vertical gate electrode contact each other.

A memory device includes at least one bit line, at least one word line, and at least one memory cell. The memory cell includes a first transistor, a plurality of data storage elements, and a plurality of second transistors corresponding to the plurality of data storage elements. The first transistor includes a gate electrically coupled to the word line, a first source/drain, and a second source/drain. Each data storage element among the plurality of data storage elements and the corresponding second transistor are electrically coupled in series between the first source/drain of the first transistor and the bit line.

A memory device may be provided, including first, second and third electrodes, first and second mask elements and a switching layer. The first mask element may be arranged over a portion of and laterally offset from the first electrode. The second electrode may be arranged over the first mask element. The second mask element may be arranged over the second electrode. The third electrode may be arranged over a portion of and laterally offset from the second mask element. The switching layer may be arranged between the first electrode and the third electrode, along a first side surface of the first mask element, a first side surface of the second electrode and a first side surface of the second mask element.

A non-volatile memory device includes arrays of non-volatile memory cells that are configured to the store weights for a recurrent neural network (RNN) inference engine with a gated recurrent unit (GRU) cell. A set three non-volatile memory arrays, such as formed of storage class memory, store a corresponding three sets of weights and are used to perform compute-in-memory inferencing. The hidden state of a previous iteration and an external input are applied to the weights of the first and the of second of the arrays, with the output of the first array used to generate an input to the third array, which also receives the external input. The hidden state of the current generation is generated from the outputs of the second and third arrays.

Memory devices have an array of elements in two or more dimensions. The memory devices use multiple access lines arranged in a grid to access the memory devices. Memory cells are located at intersections of the access lines in the grid. Drivers are used for each access line and configured to transmit a corresponding signal to respective memory cells of the plurality of memory cells via a corresponding access line. The memory devices also include compensation circuitry configured to determine which driving access lines driving a target memory cell of the plurality of memory cells has the most distance between the target memory cell and a respective driver. The plurality of access lines comprise the driving access lines. The compensation circuitry also is configured to output compensation values to adjust the voltages of the driving access lines based on a polarity of the voltage of the longer driving access line.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a conductive element disposed within a dielectric structure over the substrate. The conductive element has a top surface extend between outermost sidewalls of the conductive element. A first resistive random access memory (RRAM) element is arranged within the dielectric structure and has a first data storage layer directly contacting the top surface of the conductive element. A second RRAM element is arranged within the dielectric structure and has a second data storage layer directly contacting the top surface of the conductive element.

A true random number generator device based on a diffusive memristor is disclosed. The random number generator device includes a diffusive memristor driven by a pulse generator circuit. The diffusive memristor produces a stochastically switched output signal. A comparator circuit receives the stochastically switched output signal from the diffusive memristor and generates an output signal having a random pulse width. An AND gate logic circuit is driven by a clock signal and the output signal from the comparator circuit. The AND gate logic circuit produces a combined output signal. A counter circuit receives the combined output signal from the AND gate logic circuit and generates a random bit string output signal.

One embodiment of a memory device comprises a selector and a storage capacitor in series with the selector. A further embodiment comprises a conductive bridging RAM (CBRAM) in parallel with a storage capacitor coupled between the selector and zero volts. A plurality of memory devices form a 1S-1C or a 1S-1C-CBRAM cross-point DRAM array with 4F.sup.2 or less density.

In some embodiments, a semiconductor device is provided. The semiconductor device includes a semiconductor substrate having a first semiconductor material layer separated from a second semiconductor material layer by an insulating layer. A first access transistor is arranged on the first semiconductor material layer, where the first access transistor has a pair of first source/drain regions having a first doping type. A second access transistor is arranged on the first semiconductor material layer, where the second access transistor has a pair of second source/drain regions having a second doping type opposite the first doping type. A resistive memory cell having a bottom electrode and an upper electrode is disposed over the semiconductor substrate, where one of the first source/drain regions and one of the second source/drain regions are electrically coupled to the bottom electrode.

A switch element includes a first wiring line that is provided in a first insulating film and extends in a first direction; a second wiring line that is provided in a second insulating film and extends in a second direction that intersects the first direction; an ion conductive layer sandwiched between the first wiring line and the second wiring line and directly in contact with the second wiring line in an intersection region where the first wiring line and the second wiring line intersect, and enabled to conduct metal ions supplied from the second wiring line; and a metal oxide film sandwiched between the first wiring line and the ion conductive layer.