A switch device includes a first electrode, a second electrode, and a switch layer. The second electrode is disposed to face the first electrode. The switch layer is provided between the first electrode and the second electrode. The switch layer contains an amorphous material made of at least germanium (Ge) and one of nitrogen (N) and oxygen (O).

Concurrent access of multiple memory cells in a cross-point memory array is disclosed. In one aspect, a forced current approach is used in which, while a select voltage is applied to a selected bit line, an access current is driven separately through each selected word line to concurrently drive the access current separately through each selected memory cell. Hence, multiple memory cells are concurrently accessed. In some aspects, the memory cells are accessed using a self-referenced read (SRR), which improves read margin. Concurrently accessing more than one memory cell in a cross-point memory array improves bandwidth. Moreover, such concurrent accessing allows the memory system to be constructed with fewer, but larger cross-point arrays, which increases array efficiency. Moreover, concurrent access as disclosed herein is compatible with memory cells such as MRAM which require bipolar operation.

A memory device includes a cell block including memory cells; a control logic; and a correction block in a dummy region in a core region. The correction block may include first metal lines extending in a first direction; vias extending in a second direction; and second metal lines extending in a third direction. Each of the second metal lines may have a metal center line defining a center of each of the second metal lines in the first direction. Each of the vias may have a via center line defining a center of each of th vias in the first direction. At least one metal center line and at least one via center line may be spaced apart from each other by a first gap in the first direction.

A two-terminal device comprises a bottom electrode. A device element is formed upon the bottom electrode. The two-terminal device also comprises a top electrode that is formed upon the device element. The bottom electrode and the top electrode are aligned. The bottom electrode and top electrode also have a same width and depth.

A semiconductor device may include: first conductive lines; second conductive lines disposed on the first conductive lines to be spaced apart from the first conductive lines; selector layer disposed between the first conductive lines and the second conductive lines; a variable resistance layer disposed between the first conductive lines and the second conductive lines; and a first electrode layer including graphene and disposed between the variable resistance layer and the selector layer.

A memory cell includes a first diode, a second diode, and a random access memory cell element. The first diode and the random access memory cell element are series connected between a bit line and a word line. The second diode and the random access memory cell element are series connected between the word line and a reset line. A set path is formed through the first diode and the random access memory cell element, and a reset path is formed through the random access memory cell element and the second diode. The first diode is configured to performed a read operation and a set operation. The second diode is configured to perform a reset operation. The memory cell has higher forward current, lower leakage current and smaller size comparing with conventional memory cells.

The present invention is directed to a memory device that includes an array of memory cells. Each of the memory cells includes a memory element connected to a two-terminal selector element. The two-terminal selector element includes a first electrode and a second electrode with a switching layer interposed therebetween. The switching layer includes a plurality of metal-rich clusters embedded in a nominally insulating matrix. One or more conductive paths are formed in the switching layer when an applied voltage to the memory cell exceeds a threshold level. Each of the memory cells may further include an intermediate electrode interposed between the memory element and the two-terminal selector element. The two-terminal selector element may further include a third electrode formed between the first electrode and the switching layer, and a fourth electrode formed between the second electrode and the switching layer.

The present invention is directed to a memory device having a via landing pad in the peripheral circuit that minimizes the memory cell size. A device having features of the present invention comprises a peripheral circuit region and a magnetic memory cell region including at least a magnetic tunnel junction (MTJ) element. The peripheral circuit region comprises a substrate and a bottom contact formed therein; a landing pad including a first magnetic layer structure formed on top of the bottom contact and a second magnetic layer structure separated from the first magnetic layer structure by an insulating tunnel junction layer, wherein each of the insulating tunnel junction layer and the second magnetic layer structure has an opening aligned to each other; and a via partly embedded in the landing pad and directly coupled to the first magnetic layer structure through the openings.

In a memory cell unit array, memory cell units each constituted of first wires, second wires, and a nonvolatile memory cell are arranged in a two-dimensional matrix form in a first direction and a second direction. Each of the memory cell units includes a control circuit below it. The control circuit is constituted of a first control circuit and a second control circuit. The second wires are connected to the second control circuit. Some of the first wires that constitute the memory cell unit are connected to the first control circuit that constitutes this memory cell unit. Others of the first wires are connected to the first control circuit that constitutes an adjacent memory cell unit adjacent thereto in the first direction.

Various embodiments of the present application are directed towards a method for forming a metal-insulator-metal (MIM) capacitor comprising an enhanced interfacial layer to reduce breakdown failure. In some embodiments, a bottom electrode layer is deposited over a substrate. A native oxide layer is formed on a top surface of the bottom electrode layer and has a first adhesion strength with the top surface. A plasma treatment process is performed to replace the native oxide layer with an interfacial layer. The interfacial layer is conductive and has a second adhesion strength with the top surface of the bottom electrode layer, and the second adhesion strength is greater than the first adhesion strength. An insulator layer is deposited on the interfacial layer. A top electrode layer is deposited on the insulator layer. The top and bottom electrode layers, the insulator layer, and the interfacial layer are patterned to form a MIM capacitor.