A memory array, a semiconductor chip and a method for forming the memory array are provided. The memory array includes first signal lines, second signal lines and memory cells. The first signal lines extend along a first direction. The second signal lines extend along a second direction over the first signal lines. The memory cells are defined at intersections of the first and second signal lines, and respectively include a resistance variable layer, a switching layer, an electrode layer and a carbon containing dielectric layer. The switching layer is overlapped with the resistance variable layer. The electrode layer lies between the resistance variable layer and the switching layer. The carbon containing layer laterally surrounds a stacking structure including the resistance variable layer, the switching layer and the electrode layer.

The present disclosure generally relates to non-volatile memory arrays and memory devices in which a leakage current through an OTS is utilized to pre-charge a circuit of a memory chip. By running an additional wire on each side of a tile which is orthogonal to, above, or below the X and Y select wires, a high value resistance material, such as an OTS, may be deposited at the intersection. The OTS allows the word line or bit line to be selected without pulling excessive leakage to the select wire from the bias voltage, such as V/2. A thickness of the OTS is adjusted such that the V.sub.t of the OTS is greater than V/2, with margin, and the OTS does not turn on when the OTS is selected. A resistance is created between the V/2 wire and the word line select wire or the bit line select wire.

An integrated circuit which enables lower cost yet provides superior performance compared to standard silicon integrated circuits by utilizing thin film transistors (TFTs) fabricated in BEOL. Improved memory circuits are enabled by utilizing TFTs to improve density and access in a three dimensional circuit design which minimizes die area. Improved I/O is enabled by eliminating the area on the surface of the semiconductor dedicated to I/O and allowing many times the number of I/O available. Improved speed and lower power are also enabled by the shortened metal routing lines and reducing leakage.

All-printed paper-based substrate memory devices are described. In an embodiment, a paper-based memory device is prepared by coating one or more areas of a paper substrate with a conductor material such as a carbon paste, to form a first electrode of a memory, depositing a layer of insulator material, such as titanium dioxide, over one or more areas of the conductor material, and depositing a layer of metal over one or more areas of the insulator material to form a second electrode of the memory. In an embodiment, the device can further include diodes printed between the insulator material and the second electrode, and the first electrode and the second electrodes can be formed as a crossbar structure to provide a WORM memory. The various layers and the diodes can be printed onto the paper substrate by, for example, an ink jet printer.

A memory device including a first array of rail structures that extend along a first horizontal direction, in which each of the rail structures are formed to serve as a bottom electrode, and a second array of rail structures that laterally extend along a second horizontal direction and are laterally spaced apart along the first horizontal direction. Each of the rail structures in the second array are formed to server as a top electrode. The memory device also includes a continuous dielectric memory layer located between the first array of rail structures and the second array of rail structures. The continuous dielectric memory layer providing protection from current leakage between the rail structures of the first array and the rail structures of the second array.

A switch includes a first electrode layer, a second electrode layer disposed over the first electrode layer, and a selecting element layer interposed between the first electrode layer and the second electrode layer. The selecting element layer includes a gas region in which a current flows or does not flow according to a voltage applied to the switch. When the current flows, the switch is in an on-state, and, when the current does not flow, the switch is in an off-state.

Methods and apparatuses for a resistive random access memory (RRAM) device are disclosed. The RRAM device comprises a bottom electrode, a resistive switching layer disposed on the bottom electrode, and a top electrode disposed on the resistive switching layer. The resistive switching layer is made of a composite of a metal, Si, and O. There may be an additional tunnel barrier layer between the top electrode and the bottom electrode. The top electrode and the bottom electrode may comprise multiple sub-layers.

A RRAM device having a diode device structure coupled to a variable resistance layer is disclosed. The diode device structure can either be embedded into or fabricated over the substrate. A memory device having an array of said RRAM devices can be fabricated with multiple common bit lines and common word lines.

A semiconductor structure comprises a conductive bridge random access memory device and an access device connected in series with the conductive bridge random access memory device. The conductive bridge random access memory device and the access device are arranged in a vertical stack. The vertical stack has a sidewall profile that increases in width from a bottom surface of the vertical stack to a top surface of the vertical stack.

A variable resistance memory device and a method of manufacturing the same, the variable resistance memory device including a substrate including a first memory region and a second memory region; a plurality of first memory cells on the first memory region; and a plurality of second memory cells on the second memory region, wherein each of the first memory cells includes a first resistance element and a selection element, each of the second memory cells includes a second resistance element, and a maximum value of a variable resistance of the second resistance element is less than a maximum value of a variable resistance of the first resistance element.