An array device and a writing method thereof are provided. A synapse array device includes: a crossbar array, in which a resistive memory element is connected to each intersection of a plurality of row lines and a plurality of column lines; a row select/drive circuit selecting a row line of the crossbar array and applying a pulse signal to the selected row line; a column select/drive circuit selecting a column line of the crossbar array and applying a pulse signal to the selected column line; and a writing part writing to the resistive memory element connected to the selected row line and the selected column line. A first write voltage with controlled pulse width is applied to the selected row line, and a second write voltage with controlled pulse width is applied to the selected column line to perform set writing of the resistive memory element.

A nonvolatile memory device according to an embodiment includes a substrate having an upper surface, a gate line structure disposed over the substrate, a gate dielectric layer covering one sidewall surface of the gate line structure and disposed over the substrate, a channel layer disposed to cover the gate dielectric layer and disposed over the substrate, a bit line structure and a resistance change structure to contact different portions of the channel layer over the substrate, and a source line structure disposed in the resistance change structure. The gate line structure includes at least one gate electrode layer pattern and interlayer insulation layer pattern that are alternately stacked along a first direction perpendicular to the substrate, and extends in a second direction perpendicular to the first direction.

A memory device includes a memory array including a plurality of memory cells arranged in rows and columns. A closed loop bias generator is configured to output a column select signal to the memory array. A current limiter receives an output of the closed loop bias generator. The current limiter is coupled to a plurality of the columns of the memory array.

Disclosed herein are related to a memory system and a method of operating the memory system. In one aspect, resistances of a first memory cell, a second memory cell, a third memory cell, and a fourth memory cell are individually set. In one aspect, the first memory cell and the second memory cell are coupled to each other in series between a first line and a second line, and the third memory cell and the fourth memory cell are coupled to each other in series between the second line and a third line. In one aspect, current through the second line according to a parallel resistance of i) a first series resistance of the first memory cell and the second memory cell, and ii) a second series resistance of the third memory cell and the fourth memory cell is sensed. According to the sensed current, multi-level data can be read.

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.

The apparatuses and methods described herein may operate to measure a voltage difference between a selected access line and a selected sense line associated with a selected cell of a plurality of memory cells of a memory array. The voltage difference may be compared with a reference voltage specified for a memory operation. A selection voltage(s) applied to the selected cell for the memory operation may be adjusted responsive to the comparison, such as to dynamically compensate for parasitic voltage drop.

The present disclosure provides a memory apparatus and a method for accessing a 3D vertical memory array. The 3D vertical memory array comprises word lines organized in planes separated from each other by insulating material, bit lines perpendicular to the word line planes, memory cells coupled between a respective word line and a respective bit line. The apparatus also comprises a controller configured to select multiple word lines, select multiple bit lines, and simultaneously access multiple memory cells, with each memory cell at a crossing of a selected word line and a selected bit line. The method comprises selecting a multiple word lines, selecting multiple bit lines and simultaneously accessing multiple memory cells, with each memory cell at a crossing of a selected word line of the selected multiple word lines and a selected bit line of the selected multiple bit lines. A method of manufacturing a 3D vertical memory array is also described.

A memory device includes transistors and a memory cell array disposed over and electrically coupled to the transistors. The memory cell array includes word lines, bit line columns, and data storage layers interposed between the word lines and the bit line columns. A first portion of the word lines on odd-numbered tiers of the memory cell array is oriented in a first direction, and a second portion of the word lines on even-numbered tiers of the memory cell array is oriented in a second direction that is angularly offset from the first direction. The bit line columns pass through the odd-numbered tiers and the even-numbered tiers, and each of the bit line columns is encircled by one of the data storage layers. A semiconductor die and a manufacturing method of a semiconductor structure are also provided.

A neuromorphic computing device includes first and second memory cell arrays, and an analog-to-digital converting circuit. The first memory cell array includes a plurality of resistive memory cells, generates a plurality of read currents based on a plurality of input signals and a plurality of data, and outputs the plurality of read currents through a plurality of bitlines or source lines. The second memory cell array includes a plurality of reference resistive memory cells and an offset resistor, and outputs a reference current through a reference bitline or a reference source line. The analog-to-digital converting circuit converts the plurality of read currents into a plurality of digital signals based on the reference current. The offset resistor is connected between the reference bitline and the reference source line.

A variable resistive memory device includes a memory cell, a first current-applying block, a second current-applying block and a mode setting circuit. The memory cell includes a first electrode, a second electrode, and a memory layer, the memory layer interposed between the first electrode and the second electrode. The first current-applying block is configured to flow a first current to the first electrode that flows from the first electrode to the second electrode. The second current-applying block is configured to flow a second current to the second electrode that flows from the second electrode to the first electrode. The mode setting circuit is configured to selectively provide any one of the first electrode of the first current-applying block and the second electrode of the second current-applying block with a first voltage. When the memory cell is selected, the selected current-applying block, among the first current-applying block and the second current-applying block, is driven. When the first current-applying block is selected, a second voltage is applied to the second electrode. When the second current-applying block is selected, the second voltage is applied to the first electrode. The first voltage has a voltage level by a threshold voltage higher than the second voltage.