A method for reading memory cells is described. The method may include applying a first read voltage to a plurality of memory cells, detecting first threshold voltages exhibited by the plurality of memory cells in response to application of the first read voltage, associating a first logic state to one or more cells of the plurality of memory cells, applying a second read voltage to the plurality of memory cells, where the second read voltage has the same polarity of the first read voltage and a higher magnitude than an expected highest threshold voltage of memory cells in the first logic state, and detecting second threshold voltages exhibited by the plurality of memory cells in response to application of the second read voltage, among other aspects. A related circuit, a related memory device and a related system are also disclosed.

A single memory cell has the functions of a storage element and a selector. The memory cell includes a P-type layer, a tunneling structure and an N-type layer. The tunneling structure is formed on the P-type layer. The N-type layer is formed on the tunneling structure. The tunneling structure is a stack structure including a first material layer, a second material layer and a third material layer. By adjusting a bias voltage that is applied to the P-type layer and the N-type layer, the tunneling structure is controlled to be in the amorphous state or the crystalline state. Consequently, the memory cell has the memorizing and storing functions. The memory cell has the P-type layer, the tunneling structure and the N-type layer. By adjusting the bias voltage, the function of the selector is achieved.

The present disclosure includes apparatuses, methods, and systems for multi-state programming of memory cells. An embodiment includes a memory having a plurality of memory cells, and circuitry configured to program a memory cell of the plurality of memory cells to one of four possible data states by applying a first voltage pulse to the memory cell wherein the first voltage pulse has a first polarity and a first magnitude, and applying a second voltage pulse to the memory cell wherein the second voltage pulse has a second polarity and a second magnitude, and the second voltage pulse is applied for a shorter duration than the first voltage pulse.

In an example, a method may include comparing input data to stored data stored in a memory cell and determining whether the input data matches the stored data based on whether the memory cell snaps back in response to an applied voltage differential across the memory cell.

In accordance with an example embodiment of the present invention, an apparatus is disclosed. The apparatus includes a resistive memory component including an active material and two or more electrodes in electrical contact with the active material of the resistive memory component; and a selector component providing control over the resistive memory component, the selector component including an active material and two or more electrodes in electrical contact with the active material of the selector component. The resistive memory component and the selector component share one or more electrodes, and the resistive memory component and the selector component share at least part of the active material. A method and apparatus for producing the apparatus are also disclosed.

In one example, a volatile selector is switched from a low conduction state to a first high conduction state with a first voltage level and then the first voltage level is removed to activate a relaxation time for the volatile selector. The relaxation time is defined as the time the first volatile selector transitions from the high conduction state back to the low conduction state. The volatile selector is switched with a second voltage level of opposite polarity to the first voltage level to significantly reduce the relaxation time of the volatile selector.

A multilayered memristor includes a semiconducting n-type layer, a semiconducting p-type layer, and a semiconducting intrinsic layer. The semiconducting n-type layer includes one or both of anion vacancies and metal cations. The semiconducting p-type layer includes one or both of metal cation vacancies and anions. The semiconducting intrinsic layer is coupled between the n-type layer and the p-type layer to form an electrical series connection through the n-type layer, the intrinsic layer, and the p-type layer.

A circuit component that exhibits a region of negative differential resistance includes: a first layer of material; and a second layer of material in contact with the first layer of material, the contact forming a first self-heating interface. The first self-heating interface is structured such that an electrical current flowing from the first layer of material to the second layer of material encounters an electrical impedance occurring at the first interface that is greater than any electrical impedance occurring in the first and second layers of material, wherein heating occurring at the first interface is dominated by Joule heating caused by the electrical impedance occurring at the first interface, and wherein the electrical impedance occurring at the first interface decreases with increasing temperature to induce a region of negative differential resistance.

The present disclosure relates to a memory device comprising a plurality of memory cells, each memory cell being programmable to a logic state corresponding to a threshold voltage exhibited by the memory cell in response to an applied voltage, and a logic circuit portion operatively coupled to the plurality of memory cells, wherein the logic circuit portion is configured to scan memory addresses of the memory device, and to generate seasoning pulses to be applied to the addressed pages of the memory device. A related electronic system and related methods are also disclosed.

Memory devices for embedded applications are described. A memory device may include an array of memory cells having a first area and configured to operate at a first voltage, and circuitry having a second area that at least partially overlaps the first area. The circuitry may be configured to operate at a second voltage lower than the first voltage. The circuitry maybe be further configured to access the array of memory cells using decoder circuitry configured to operate at the first voltage. The array of memory cells and the circuitry may be on a single substrate. The circuitry may include microcontroller circuitry, cryptographic controller circuitry, and/or memory controller circuitry. The memory cells may be self-selecting memory cells that each include a storage and selector element having a chalcogenide material. The memory cells may not include separate cell selector circuitry.