A memory apparatus includes an interconnect in a first dielectric above a substrate and a structure above the interconnect, where the structure includes a diffusion barrier material and covers the interconnect. The memory apparatus further includes a resistive random-access memory (RRAM) device coupled to the interconnect. The RRAM device includes a first electrode on a portion of the structure, a stoichiometric layer having a metal and oxygen on the first electrode, a non-stoichiometric layer including the metal and oxygen on the stoichiometric layer. A second electrode including a barrier material is on the non-stoichiometric layer. In some embodiments, the RRAM device further includes a third electrode on the second electrode. To prevent uncontrolled oxidation during a fabrication process a spacer may be directly adjacent to the RRAM device, where the spacer includes a second dielectric.

A semiconductor memory may include at least one memory cell. The memory cell may include: a first electrode layer; a second electrode layer separated from the first electrode layer, wherein the first and second electrode layers are coupled to receive a voltage applied to the first and second electrode layers; and a self-selecting memory layer interposed between the first electrode layer and the second electrode layer and configured to store data and operable to disconnect or connect a conducting path between the first electrode layer and the second electrode layer, to respond to the voltage applied to the first and second electrode layers, wherein the self-selecting memory layer includes an insulating material layer, a first dopant that creates a shallow trap providing a path for conductive carriers in the insulating material layer, and a second dopant that is movable in the insulating material layer according to a polarity of the voltage applied to the first and second electrode layers.

A memory cell includes a first resistive memory element, a second resistive memory element electrically coupled with the first resistive memory element at a common node, and a switching element comprising an input terminal electrically coupled with the common node, the switching element comprising a driver configured to float during one or more operations.

Aspects of the subject disclosure may include, for example, applying a setting voltage across first and second electrodes, wherein a nanowire with a first electrical resistance is electrically connected between the first and second electrodes, wherein the applying of the setting voltage causes a migration of ions from the first and/or second electrodes to a surface of the nanowire, and wherein the migration of ions effectuates a reduction of electrical resistance of the nanowire from the first electrical resistance to a second electrical resistance that is lower than the first electrical resistance; and applying a reading voltage across the pair of electrodes, wherein the reading voltage is less than the setting voltage, and wherein the reading voltage is sufficiently small such that the applying of the reading voltage causes no more than an insignificant change of the electrical resistance of the nanowire from the second electrical resistance. Other embodiments are disclosed.

A memristor includes a bottom electrode, a top electrode, and an active region disposed therebetween. The active region has an electrically conducting filament in an electrically insulating medium, extending between the bottom electrode and the top electrode. The memristor further includes a temperature gradient element for controlling switching.

A memory device includes a plurality of memory cells, each including a switching device and an information storage device connected to the switching device and having a phase change material, the plurality of memory cells connected to a plurality of word lines and a plurality of bit lines, a decoder circuit determining at least one of the plurality of memory cells to be a selected memory cell, and a program circuit configured to input a programming current to the selected memory cell to perform a programming operation and configured to detect a resistance of the selected memory cell to adjust a magnitude of the programming current.

There is provided a non-volatile memory device comprising: a substrate; a lower electrode disposed on the substrate; a resistance layer disposed on the lower electrode; and an upper electrode disposed on the resistance layer, wherein the resistance layer include a stack of a graphene oxide film and an iron oxide film, wherein a resistance value of the resistance layer varies based on a voltage applied to the upper electrode.

A memory device includes a sense amplifier coupled to a first read voltage during a first phase of a read operation and a second read voltage during a second phase of the read operation. A first and second bias voltages are based on the first and second read voltages and corresponding current on a bit line. A first capacitor includes a terminal coupled to the first and second bias voltages. A first amplifier includes an input coupled to another terminal of the first capacitor and another input coupled to a common mode voltage during the first phase and to a reference voltage during the second phase. A second capacitor includes a terminal coupled to an output of the first amplifier. A second amplifier includes an inverting input coupled to another terminal of the second capacitor and another input coupled to a common mode voltage.

The disclosed technology generally relates to semiconductor devices and more particularly to memory or storage devices based on resistive switching, and to methods of making and using such devices. In one aspect, a resistive switching memory device includes a first electrode and a second electrode having interposed therebetween a first inner region and a second inner region, where the first and second inner regions contacting each other. The first inner region includes one or more metal oxide layers and the second inner region consists of a plurality of layers, where each of the layers of the second inner region is an insulating, a semi-insulating or a semiconducting layer. The second inner region comprises one or more layers having a stoichiometric or off-stoichiometric composition of a material selected from the group consisting of SiGe.sub.x, SiN.sub.x, AlO.sub.x, MgO.sub.x, AlN.sub.x, SiN.sub.x, HfO.sub.x, HfSiO.sub.x, ZrO.sub.x, ZrSiO.sub.x, GdAlO.sub.x, DyScO.sub.x, TaO.sub.x and combinations thereof. The second inner region comprises one or more silicon-containing layers, such that one of the one or more silicon-containing layers contacts the first inner region.

Numerous embodiments are disclosed for compensating for differences in the slope of the current-voltage characteristic curve among reference transistors, reference memory cells, and flash memory cells during a read operation in an analog neural memory in a deep learning artificial neural network. In one embodiment, a method comprises receiving an input voltage, multiplying the input voltage by a coefficient to generate an output voltage, applying the output voltage to a gate of a selected memory cell, performing a sense operating using the selected memory cell and a reference device to determine a value stored in the selected memory cell, wherein a slope of a current-voltage characteristic curve of the reference device and a slope of the current-voltage characteristic curve of the selected memory cell are approximately equal during the sense operation.