An aspect of the invention relates to an elementary cell that includes a breakdown layer made of dielectric having a thickness that depends on a breakdown voltage, a device and a non-volatile resistive memory mounted in series, the device including an upper selector electrode, a lower selector electrode, a layer made in a first active material, referred to as active selector layer, the device being intended to form a volatile selector; the memory including an upper memory electrode, a lower memory electrode, a layer made in at least one second active material, referred to as active memory layer.

An aspect of the invention relates to an elementary cell that includes a breakdown layer made of dielectric having a thickness that depends on a breakdown voltage, a device and a non-volatile resistive memory mounted in series, the device including an upper selector electrode, a lower selector electrode, a layer made in a first active material, referred to as active selector layer, the device being intended to form a volatile selector; the memory including an upper memory electrode, a lower memory electrode, a layer made in at least one second active material, referred to as active memory layer.

The disclosure concerns a resistive memory cell, including a stack of a selector, of a resistive element, and of a layer of phase-change material, the selector having no physical contact with the phase-change material. In one embodiment, the selector is an ovonic threshold switch formed on a conductive track of a metallization level.

A method of manufacturing an electronic device comprises: forming a plurality of line patterns on a substrate extending in a first direction and including a first conductive line and a memory pattern; forming a first liner layer on sidewalls of each of the plurality of line patterns, the first liner layer including a plurality of layers having different energy band gaps; forming an insulating interlayer on the substrate; forming a plurality of second conductive lines on the line patterns and the insulating interlayer; etching the first liner layer, the insulating interlayer and the memory pattern using the second conductive lines as an etch barrier to expose the first conductive line to form a plurality of memory cells; and forming a second liner layer on both sidewalls of each of the memory cells, the etched first liner layer and both sidewalls of the etched insulating interlayer.

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.

A method for making a phase change memory includes a step of forming an array of phase change memory cells, with each cell being separated from neighboring cells in the same line of the array and from neighboring cells in the same column of the array, by the same first distance. The method further includes a step of etching one memory cell out of N, with N being at least equal to 2, in each line or each column.

A semiconductor device includes a first transistor formed on a first side of a substrate. The semiconductor device includes a first power rail structure vertically disposed over the first transistor, a second power rail structure vertically disposed over the first power rail structure, and a memory portion vertically disposed over the second power rail structure. The first power rail structure, and a second power rail structure, and the memory portion are all disposed on a second side of the substrate opposite to the first side.

Various embodiments of the present application are directed towards a resistive random-access memory (RRAM) cell including a top-electrode barrier layer configured to block the movement of nitrogen or some other suitable non-metal element from a top electrode of the RRAM cell to an active metal layer of the RRAM cell. Blocking the movement of non-metal element may be prevent formation of an undesired switching layer between the active metal layer and the top electrode. The undesired switching layer would increase parasitic resistance of the RRAM cell, such that top-electrode barrier layer may reduce parasitic resistance by preventing formation of the undesired switching layer.

Various embodiments of the present application are directed towards a method for forming an integrated chip. The method includes forming a dielectric structure over a substrate. A first conductive wire is formed along the dielectric structure. The first conductive wire extends laterally along a first direction. A memory stack is formed on a top surface of the first conductive wire. A second conductive wire is formed over the memory stack. The second conductive wire extends laterally along a second direction orthogonal to the first direction. An upper conductive via is formed on the top surface of the first conductive wire. An upper surface of the upper conductive via is above the second conductive wire.

Row and/or column electrode lines for a memory device are staggered such that gaps are formed between terminated lines. Vertical interconnection to central points along adjacent lines that are not terminated are made in the gap, and vertical interconnection through can additionally be made through the gap without contacting the lines of that level.