Conductive bridge random access memory (CBRAM) devices with low thermal conductivity electrolyte sublayers are described. In an example, a conductive bridge random access memory (CBRAM) device includes a conductive interconnect disposed in an inter-layer dielectric (ILD) layer disposed above a substrate. The CBRAM device also includes a CBRAM element disposed on the conductive interconnect. The CBRAM element includes an active electrode layer disposed on the conductive interconnect, and a resistance switching layer disposed on the active electrode layer. The resistance switching layer includes a first electrolyte material layer disposed on a second electrolyte material layer, the second electrolyte material layer disposed on the active electrode layer and having a thermal conductivity lower than a thermal conductivity of the first electrolyte material layer. A passive electrode layer is disposed on the first electrolyte material of the resistance switching layer.

In some examples, a hybrid memory device includes multiple memory cells, where a given memory cell of the multiple memory cells includes a volatile memory element having a plurality of layers including electrically conductive layers and a dielectric layer between the electrically conductive layers, and a non-volatile resistive memory element to store different data states represented by respective different resistances of the non-volatile resistive memory element, the non-volatile resistive memory element having a plurality of layers including electrically conductive layers and a resistive switching layer between the electrically conductive layers of the non-volatile resistive memory element.

A resistive memory cell includes a barrier layer containing at least one of silicon and germanium, and a metal oxide layer including an oxide of a metal element that provides a reversible chemical reaction under a bidirectional electrical bias at an interface with the barrier material layer. The reversible chemical reaction is selected from a silicidation reaction between the barrier material layer and the metal element, a germanidation reaction between the barrier material layer and the metal element, oxidation of the metal element, and reduction of the metal element.

A resistive memory device and a method of operation of the resistive memory device are provided. The resistance memory device includes a resistance change layer that has a tunneling film and has many states. The conductance is changed symmetrically in a SET operation and a RESET operation. Thus, the resistive memory device can be used for efficient and accurate data storage as a RRAM in a high-capacity memory array, and as a synaptic device controlling the connection strength of a synapse in a neuromorphic system.

The disclosed subject matter relates generally to structures for use in memory devices. More particularly, the present disclosure relates to three terminal resistive random-access (ReRAM) memory structures having source, drain, and control electrodes. The present disclosure provides a memory structure including a source electrode, a drain electrode, a control electrode laterally between the source electrode and the drain electrode, a hole generating layer above the control electrode, a dielectric channel layer above the hole generating layer, the dielectric channel layer contacts the source electrode and the drain electrode, a first spacer layer on a first side of the control electrode, and a second spacer layer on a second side of the control electrode. The first spacer layer and the second spacer layer isolate the source electrode and the drain electrode from the control electrode and the hole generating layer.

A phase change memory apparatus comprises at least one heating layer; and at least one phase change layer comprising a vanadium dioxide layer, wherein each of the at least one phase change layer is set corresponding to each of the at least one heating layer, the at least one heating layer is configured to heat the at least one phase change layer.

According to embodiments, a semiconductor memory device includes a first electrode, a second electrode, a memory cell, and a control circuit. The memory cell is provided between the first electrode and the second electrode and includes a metal film and a resistance change film. The control circuit applies a voltage between the first electrode and the second electrode to perform transition of a resistive state of the memory cell. The control circuit performs a first writing operation by applying a first pulse having a voltage of a first polarity to the memory cell and applying a second pulse having a voltage of the first polarity smaller than the voltage of the first pulse to the memory cell continuously after applying the first pulse.

A resistive memory cell includes a barrier layer containing at least one of silicon and germanium, and a metal oxide layer including an oxide of a metal element that provides a reversible chemical reaction under a bidirectional electrical bias at an interface with the barrier material layer. The reversible chemical reaction is selected from a silicidation reaction between the barrier material layer and the metal element, a germanidation reaction between the barrier material layer and the metal element, oxidation of the metal element, and reduction of the metal element.

A memory device includes a first conductive layer, a second conductive layer, and a variable resistance layer disposed between the first and second conductive layers. The variable resistance layer includes a first layer containing a semiconductor or a first metal oxide, a second layer disposed between the first layer and the first conductive layer, and containing a second metal oxide, and a first amorphous layer disposed between the second layer and the first conductive layer.

Memory systems and memory programming methods are described. According to one aspect, a memory system includes program circuitry configured to provide a program signal to a memory cell to program the memory cell from a first memory state to a second memory state, detection circuitry configured to detect the memory cell changing from the first memory state to the second memory state during the provision of the program signal to the memory cell to program the memory cell, and wherein the program circuitry is configured to alter the program signal as a result of the detection and to provide the altered program signal to the memory cell to continue to program the memory cell from the first memory state to the second memory state.