The present disclosure relates to a resistive random access memory (RRAM) device architecture, that includes a thin single layer of a conductive etch-stop layer between a lower metal interconnect and a bottom electrode of an RRAM cell. The conductive etch-stop layer provides simplicity in structure and the etch-selectivity of this layer provides protection to the underlying layers. The conductive etch stop layer can be etched using a dry or wet etch to land on the lower metal interconnect. In instances where the lower metal interconnect is copper, etching the conductive etch stop layer to expose the copper does not produce as much non-volatile copper etching by-products as in traditional methods. Compared to traditional methods, some embodiments of the disclosed techniques reduce the number of mask step and also reduce chemical mechanical polishing during the formation of the bottom electrode.

A phase-change memory element with an electrically isolated conductor is provided. The phase-change memory element includes: a first electrode and a second electrode; a phase-change material layer electrically connected to the first electrode and the second electrode; and at least two electrically isolated conductors, disposed between the first electrode and the second electrode, directly contacting the phase-change material layers.

Semiconductor devices and methods of manufacturing are provided in which memory cells are manufactured with a double sided word line structure. In embodiments a first word line is located on a first side of the memory cells and a second word line is located on a second side of the memory cells opposite the first side.

A memory cell includes a bottom electrode, a memory element, spacers, a selector and a top electrode. The memory element is located on the bottom electrode and includes a first conductive layer, a second conductive layer and a storage layer. The first conductive layer is electrically connected to the bottom electrode. The second conductive layer is located on the first conductive layer, wherein a width of the first conductive layer is smaller than a width of the second conductive layer. The storage layer is located in between the first conductive layer and the second conductive layer. The spacers are located aside the second conductive layer and the storage layer. The selector is disposed on the spacers and electrically connected to the memory element. The top electrode is disposed on the selector.

An electronic circuit includes a plurality of word lines; a plurality of bit lines intersecting the plurality of word lines at a plurality of grid points; and a plurality of resistive random-access memory cells located at the plurality of grid points. Each of the resistive random-access memory cells includes a top metal coupled to one of: a corresponding one of the word lines and a corresponding one of the bit lines; a bottom metal coupled to another one of: the corresponding one of the word lines and the corresponding one of the bit lines; a dielectric sandwiched between the top metal and the bottom metal; and a high-resistance semiconductive spacer electrically connecting the top metal and the bottom metal in parallel with the dielectric.

Embodiments disclosed herein may relate to forming reduced size storage components in a cross-point memory array. In an embodiment, a storage cell comprising an L-shaped storage component having an approximately vertical portion extending from a first electrode positioned below the storage material to a second electrode positioned above and/or on the storage component. A storage cell may further comprise a selector material positioned above and/or on the second electrode and a third electrode positioned above and/or on the selector material, wherein the approximately vertical portion of the L-shaped storage component comprises a reduced size storage component in a first dimension.

A three-dimensional semiconductor memory device may include a first conductive line extending in a first direction, a second conductive line extending in a second direction crossing the first direction, a cell stack at an intersection of the first and second conductive lines, and a gapfill insulating pattern covering a side surface of the cell stack. The cell stack may include first, second, and third electrodes sequentially stacked, a switching pattern between the first and second electrodes, and a variable resistance pattern between the second and third electrodes. A top surface of the gapfill insulating pattern may be located between top and bottom surfaces of the third electrode.

Metal-assisted chemical etching is employed to form a three-dimensional (3D) resistive random access memory (ReRAM) in which the etching aspect ratio limit is extended and the top trench and bottom trench CD uniformity is improved. The 3D ReRAM includes a metal catalyst located between a bitline electrode and a selector device. Further, the 3D ReRAM includes vertically stacked and spaced apart replacement wordline electrodes that are located adjacent to the bitline electrode.

A method of forming an array of memory cells includes forming lines of covering material that are elevationally over and along lines of spaced sense line contacts. Longitudinal orientation of the lines of covering material is used in forming lines comprising programmable material and outer electrode material that are between and along the lines of covering material. The covering material is removed over the spaced sense line contacts and the spaced sense line contacts are exposed. Access lines are formed. Sense lines are formed that are electrically coupled to the spaced sense line contacts. The sense lines are angled relative to the lines of spaced sense line contacts and relative to the access lines. Other embodiments, including structure independent of method, are disclosed.

A memory device may be provided, including a first electrode, an insulating element arranged over the first electrode, a second electrode arranged over the insulating element, a switching layer and a conductive line electrically coupled to the second electrode. Each of the first electrode, the insulating element, and the second electrode may include a first side surface and a second side surface. Centers of the first electrode, the insulating element, and the second electrode may be substantially vertically aligned. The first side surface and the second side surface of the second electrode may be substantially vertically aligned with the first side surface and the second side surface of at least one of the insulating element and the first electrode. The switching layer may be conformal to the first side surfaces and the second side surfaces of the second electrode and the insulating element.