A memory device with high storage capacity and low power consumption is provided. The memory device includes a first layer and a second layer including the first layer. The first layer includes a circuit, and the second layer includes a first memory cell. The circuit includes a bit line driver circuit and/or a word line driver circuit which transmits(s) a signal to the first memory cell. The first memory cell includes a first transistor, a second transistor, a conductor, and an MTJ element. The MTJ element includes a free layer. The free layer is electrically connected to the conductor. The first terminal of the first transistor is electrically connected to a first terminal of the second transistor through the conductor. The free layer is positioned above the conductor. The circuit includes a transistor containing silicon in a channel formation region, and each of the first transistor and the second transistor contains a metal oxide in a channel formation region.

A memory and a read and write method of memory can prevent the magnetic random-access memory (MRAM) from being easily damaged or degraded by excessive write current during use, and increase memory integration density. The memory includes: a storage unit, comprising a storage element; a source line, electrically connected to a first end of the storage element; the memory is configured to change a storage state of the storage element by a first current and a second current, the first current flowing through the storage element and the second current flowing through the source line without flowing through the storage element.

A memory includes: a substrate, having a plurality of active regions arranged in an array and a plurality of word lines extending in a first direction, the active regions being inclined at a preset angle to the word lines, the active region having at least one access transistor; a plurality of bit lines, extending in a second direction perpendicular to the first direction; magnetic tunnel junctions, one end of the magnetic tunnel junction is electrically connected to one of bit lines and another end of the magnetic tunnel junction is electrically connected to two access transistors, the two access transistors electrically connected to the magnetic tunnel junction being located in two adjacent active regions, respectively.

A memory device has a plurality of bit cells, each of which includes an SRAM cell having a storage node selectively connectable to a first bit line in response to a control signal received on a first word line. Each bit cell further includes an MRAM cell selectively connectable to the storage node of the SRAM cell in response to a control signal received on a second word line.

A neuromorphic device including: a plurality of unit weighting elements connected to a bit line in a manner that shares the bit line, each of the plurality of unit weighting elements being connected to a source line and comprising a fixed layer of which a magnetization direction is fixed, a free layer of which a magnetization direction changes in parallel with or in anti-parallel with the fixed layer, and a tunnel barrier layer arranged between the fixed layer and the free layer and a plurality of drive transistors being selectively turned on according to a plurality of bit selection signals, respectively, and correspondingly driving the unit weighting elements, respectively, wherein the plurality of unit weighting elements have different resistances in such a manner as to correspond to bits, respectively, of a synapse weight.

A semiconductor memory device includes a memory cell array including a plurality of memory cells each including a resistance change type memory element configured to store a resistance state and a switch, a read determination circuit that compares a measurement signal from the memory cell selected in the memory cell array with a reference signal to determine a resistance state so as to read information from the resistance change type memory element, and a reference signal correction unit that corrects a level of the reference signal based on a selected position of the memory cell in the memory cell array.

The present disclosure is drawn to a magnetoresistive device including an array of memory cells arranged in rows and columns, each memory cell comprising a magnetic tunnel junction, each row comprising a word line, and each column comprising a bit line; a column select device that selects a bit line. The magnetoresistive device also includes a sense amplifier comprising a first input corresponding to a selected bit line, a second input corresponding to a reference bit line, and a data output. The plurality of columns comprise a reference column, the reference column comprising a conductive element coupled to the magnetic tunnel junctions in the reference column.

Systems and methods for performing word line pulse techniques in magnetoelectric junctions in accordance with embodiments of the invention are disclosed. In one embodiment, a magnetoelectric random access memory (MeRAM) circuit, including, a plurality of voltage controlled magnetic tunnel junction bits (MEJs) each magnetoelectric junction connected to the drain of an MOS transistor, the combination including three terminals, each connected to a bit, source, and at least one word line, in an array, and a driver circuit, including a bit line driver, and a word line driver the bit line driver, the driver circuit generates voltage pulses for application to the magnetoelectric junction bit, the output of the driver circuit is connected to the word line, which in turn is connected to the gate of the MOS access transistor in each MeRAM cell, thereby generating a square voltage pulse across the magnetoelectric junction bit.

Disclosed is a magnetic memory device comprising write and read word lines that extend in a first direction on a substrate, the write word line and the read word line spaced apart from each other in a second direction and parallel to a bottom surface of the substrate, first source/drain contacts on one side of the write word line and spaced apart from each other in the first direction, second source/drain contacts on one side of the read word line and spaced apart from each other in the first direction, magnetic tunnel junction patterns connected to the second source/drain contacts, and spin-orbit torque lines on the magnetic tunnel junction patterns and connected to the first source/drain contacts. The magnetic tunnel junction patterns are spaced apart from each other in a third direction. The spin-orbit torque lines are spaced apart from each other in the third direction.

A local data bus of a sense amplifier associated with one bit line is used to perform logical operations for a sensing operation performed by another sense amplifier associated with a different bit line. Each sense amplifier circuit includes a sensing node that is pre-charged, then discharged through a selected memory cell and a local data bus with a number of data latches connected. Target program data can be stored in the latches and combined in logical combinations with the sensed value of the memory cell to determine whether it has verified. By including a transfer circuit between the local data buses of a pair of sense amplifiers, the logical operations of a first sense amplifier can be performed using the local data bus of the paired sense amplifier, freeing the first sense amplifier's sense node to be concurrently pre-charged for a subsequent sensing operation, thereby improving performance.