An apparatus is provided which comprises: a magnetic junction having a magnet with perpendicular magnetic anisotropy (PMA) relative to an x-y plane of a device. In some embodiments, the apparatus comprises an interconnect partially adjacent to the structure of the magnetic junction, wherein the interconnect comprises a spin orbit material, wherein the interconnect has a pocket comprising non-spin orbit material, wherein the pocket is adjacent to the magnet of the magnetic junction. In some embodiments, the non-spin orbit material comprises metal which includes one or more of: Cu, Al, Ag, or Au.

A method for operating a memory device is provided. A first address is decoded to select a bit line of a memory device. A second address is decoded to select a word line of the memory device. A word line voltage is applied to the selected word line. A bit line voltage is applied to the selected bit line. A first bias voltage is applied to each of a plurality of unselected word lines connected to a plurality of memory cells connected to the selected bit line san a memory cell connected to both the selected bit line and the selected word line.

Various embodiments of the present application are directed towards a method of forming a memory device. The method includes forming a lower part of an interconnect structure over a substrate and forming a unipolar selector over the lower part of the interconnect structure. The method further comprises forming a data-storage element over the unipolar selector and electrically coupled in series with the unipolar selector, the data-storage element having a variable resistance. The method further comprises generating an external magnetic field by a magnetic field generator to pre-set the data-storage element to a first data state.

A memory device for storing data comprises a memory bank comprising a plurality of addressable memory cells, wherein the memory bank is divided into a plurality of segments. The memory device also comprises a cache memory operable for storing a second plurality of data words, wherein further each data word of the second plurality of data words is either awaiting write verification or is to be re-written into the memory bank. The cache memory is divided into a plurality of primary segments, wherein each primary segment of the cache memory is direct mapped to a corresponding segment of the plurality of segments of the memory bank, wherein each primary segment of the plurality of primary segments of the cache memory is sub-divided into a plurality of secondary segments, and each of the plurality of secondary segments comprises at least one counter for tracking a number of valid entries stored therein.

A non-volatile memory device is configured for in-memory computation of layers of a neural network by storing weight values as conductance values in memory cells formed of a series combination of a threshold switching selector, such as an ovonic threshold switch, and a programmable resistive element, such as a ReRAM element. By scaling the input voltages (representing inputs for the layer of the neural network) relative to the threshold values of the threshold switching selectors, dropout for inputs can be implemented to reduce overfitting by the neural network.

A magnetic memory device includes a magnetic tunnel junction (MTJ) stack, a spin-orbit torque (SOT) induction wiring disposed over the MTJ stack, a first terminal coupled to a first end of the SOT induction wiring, a second terminal coupled to a second end of the SOT induction wiring, and a selector layer coupled to the first terminal.

Embodiments of the present invention provide a storage cell and a data read/write method and storage array thereof. The storage cell includes a bit line, a tunnel junction, and four access transistors. Each access transistor includes at least an active region. The active region includes a source. The sources of the access transistors are all electrically connected to a first end of the tunnel junction. A second end of the tunnel junction is electrically connected to the bit line, and the bit line extends along a first direction. The active regions of the access transistors are isolated from one another. Long-side extension directions of the active regions of the access transistors are the same, and a first angle θ is formed between the long-side extension directions of the active regions and the first direction; wherein θ is a non-right angle.

Disclosed are examples of multiple bit magnetoresistive random access memory (MRAM) cells. A multiple bit MRAM cell may comprise a fixed layer, alternately stacked N tunnel barriers and N free layers, and a tunnel cap. N, which may represent number of bits of the MRAM cell, may be greater than or equal to two. Magnetic moment of the fixed layer may be fixed in one perpendicular direction. Magnetic moments of the free layers may be switchable from one to other perpendicular directions upon application of switch currents. The switch currents may be different for different layers. The magnetic moments of the free layers may be switched separately or otherwise independently of other free layers when the switch currents are applied separately.

A non-volatile memory includes resistive cells, write circuitry, and write detect circuitry. Each resistive cell has a resistive storage element and is coupled to a corresponding first column line and corresponding second column line. The write circuitry is configured to provide a write current through a resistive storage element of a selected resistive memory cell during a write operation based on an input data value. The write detect circuitry is configured to generate a reference voltage using a voltage at the corresponding first column line coupled to the selected resistive memory cell at an initial time of the write operation, and, during the write operation, after the initial time, provide a write detect signal based on a comparison between the voltage at the corresponding first column line coupled to the selected resistive memory cell and the reference voltage, wherein the input data value is based on the write detect signal.

In a particular implementation, a circuit comprises: a memory array including a plurality of bit cells, where each of the bit cells are coupled to a respective bit path; a first multiplexer comprising a plurality of column address locations, where each of the plurality of column address locations is coupled to the memory array and corresponds to a respective bit path capacitance; and a variable capacitance circuit coupled to a reference path and configured to substantially match reference path capacitance to each of the respective bit path capacitances.