An embodiment of the invention may include a first electrode, a second electrode, and a multi-level nonvolatile electrochemical cell located between the first electrode and second electrode. The multi-level nonvolatile electrochemical cell may have a read path and a write path through the cell, where the read path and the write path are different.

An integrated chip has an array of memory cells disposed over a semiconductor substrate and a driver circuit. The driver circuit provides the array with a read voltage that varies in relation to an approximate temperature of the memory array to ameliorate temperature dependencies in read currents. The driver circuit may vary the read voltage in an inverse relationship with temperature. The read voltage may be varied continuous or stepwise and the driver circuit may use a table lookup. Optionally, the driver circuit measures a current and modulates the read voltage until the current is within a target range. The memory cells may be multi-level phase change memory cells that include a plurality phase change element disposed between a bottom electrode and a top electrode. Modulating the read voltage to reduce temperature-dependent current variations is particularly useful for multi-level cells.

Structures including non-volatile memory elements and methods of fabricating a structure including non-volatile memory elements. First, second, and third non-volatile memory elements each include a first electrode, a second electrode, and a switching layer between the first electrode and the second electrode. A first bit line is coupled to the first electrode of the first non-volatile memory element and to the first electrode of the second non-volatile memory element. A second bit line is coupled to the first electrode of the third non-volatile memory element.

Devices and methods for accessing resistive change elements in a resistive change element array to determine resistive states of the resistive change elements are disclosed. According to some aspects of the present disclosure the devices and methods access resistive change elements in a resistive change element array through a variety of operations. According to some aspects of the present disclosure the devices and methods supply an amount of current tailored for a particular operation. According to some aspects of the present disclosure the devices and methods compensate for circuit conditions of a resistive change element array by adjusting an amount of current tailored for a particular operation to compensate for circuit conditions of the resistive change element array.

A semiconductor device may include a word line, a bit line crossing the word line, and a memory cell coupled to the word line and the bit line to receive an electrical signal to control the memory cell and including a switching material layer and an oxidation-reduction reversible material layer that is in contact with the switching material layer to allow for either oxidation reaction or reduction reaction to occur in response to different amplitudes and different polarities of the electrical signal, wherein the oxidation-reduction reversible material layer and the switching material layer responds to a first threshold voltage and a first polarity of the electrical signal to generate an oxidation interface between the switching material layer and the oxidation-reduction reversible material layer, and responds to a second threshold voltage and a second polarity of the electrical signal to reduce the generation of the oxidation interface.

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.

An embodiment of the invention may include a memory structure. The memory structure may include a first terminal connected to a first contact. The memory structure may include a second terminal connected to a second contact and a third contact. The memory structure may include a multi-level nonvolatile electrochemical cell having a variable resistance channel and a programming gate. The memory structure may include the first contact and second contact connected to the variable resistance channel. The memory structure may include the third contact is connected to the programming gate. This may enable decoupled read-write operations of the device.

A memory device is provided. The memory device includes a bottom electrode, a first data storage layer, a second data storage layer, an interfacial conductive layer and a top electrode. The first data storage layer is disposed on the bottom electrode and in contact with the bottom electrode. The second data storage layer is disposed over the first data storage layer. The interfacial conductive layer is disposed between the first data storage layer and the second data storage layer. The top electrode is disposed over the second data storage layer.

A resistive random-access memory (ReRAM) device may include a thermally engineered layer that is positioned adjacent to an active layer and configured to act as a heat sink during filament formation in response to applied voltages. The thermally engineered layer may act as one of the electrodes on the ReRAM device and may be adjacent to any side of the active layer. The active layer may also include a plurality of individual active layers. Each of the active layers may be associated with a different dielectric constant, such that the middle active layer has a dielectric constant that is significantly higher than the other two surrounding active layers.

Semiconductor memory is provided wherein a memory cell includes a capacitorless transistor having a floating body configured to store data as charge therein when power is applied to the cell. The cell further includes a nonvolatile memory comprising a resistance change element configured to store data stored in the floating body under any one of a plurality of predetermined conditions. A method of operating semiconductor memory to function as volatile memory, while having the ability to retain stored data when power is discontinued to the semiconductor memory is described.