Methods, systems, and devices for decoding architecture for memory tiles are described. Word line tiles of a memory array may each include multiple word line plates, which may each include a sheet of conductive material that includes a first portion extending in a first direction within a plane along with multiple fingers extending in a second direction within the plane. A pillar tile may include one or more pillars that extend vertically between the word line plate fingers. Memory cells may each be couple with a respective word line plate finger and a respective pillar. Word line decoding circuitry, pillar decoding circuitry, or both, may be located beneath the memory array and in some cases may be shared between adjacent pillar tiles.

A semiconductor device includes a diffusion barrier structure, a bottom electrode, a top electrode, a switching layer and a capping layer. The bottom electrode is over the diffusion barrier structure. The top electrode is over the bottom electrode. The switching layer is between the bottom electrode and the top electrode, and configured to store data. The capping layer is between the switching layer and the top electrode. The diffusion barrier structure includes a multiple-layer structure. A thermal conductivity of the diffusion barrier structure is greater than approximately 20 W/mK.

The present disclosure relates to a chalcogenide material including germanium (Ge) with a first atomic percent, selenium (Se) with a second atomic percent that is at least twice the first atomic percent of the germanium, and indium (In) with a third atomic percent less the first atomic percent of the germanium.

A projected memory device includes a carbon-based projection component. The device includes two electrodes, a memory segment, and a projection component. The projection component and the memory segment form a dual element that connects the two electrodes. The projection component extends parallel to and in contact with the memory segment. The memory segment includes a resistive memory material, while the projection component includes a thin film of non-insulating material that essentially comprises carbon. In a particular implementation, the non-insulating material and the projection component essentially comprises amorphous carbon. Using carbon and, in particular, amorphous carbon, as a main component of the projection component, allows unprecedented flexibility to be achieved when tuning the electrical resistance of the projection component.

A memory structure is provided. The memory structure includes a top terminal, a multi-level nonvolatile electrochemical cell, a bottom terminal, a pedestal contact in the same metal level as the bottom terminal, and a vertical conductor fully self-aligned to the multi-level nonvolatile electrochemical cell and extending vertically from the pedestal contact.

A semiconductor device includes gate electrodes on a substrate, a channel and a resistance pattern. The gate electrodes are spaced apart from each other in a vertical direction substantially perpendicular to an upper surface of the substrate. The channel extends through the gate electrodes in the vertical direction on the substrate. The resistance pattern includes a phase-changeable material. The resistance pattern includes a first vertical extension portion on a sidewall of the channel and extending in the vertical direction, a first protrusion portion on an inner sidewall of the first vertical extension portion and protruding in a horizontal direction substantially parallel to the upper surface of the substrate, and a second protrusion portion on an outer sidewall of the first vertical extension portion and protruding in the horizontal direction and not overlapping the first protrusion portion in the horizontal direction.

Methods, systems, and devices for techniques for manufacturing a double electrode memory array are described. A memory device may be fabricated using a sequence of fabrication steps that include depositing a first stack of materials including a conductive layer, an interface layer, and a first electrode layer. The first stack of materials may be etched to form a first set of trenches. A second stack of materials may be deposited on top of the first stack of materials. The second stack may include a second electrode layer in contact with the first electrode layer, a storage layer, and a third electrode layer. The second stack of materials may be etched to form a second set of trenches above the first set of trenches, and filled with a sealing layer and a dielectric material. The sealing layer may not extend substantially into the first set of trenches.

Disclosed is a resistive random access memory (RRAM). The RRAM includes a bottom electrode made of tungsten and a switching layer made of hafnium oxide disposed above the bottom electrode, wherein the switching layer includes a filament and one or more lateral regions including a doping material that are between a top region and a bottom region of the switching layer. The RRAM further includes a top electrode disposed above the switching layer.

Methods, systems, and devices for composite electrode material chemistry are described. A memory device may include an access line, a storage element comprising chalcogenide, and an electrode coupled with the memory element and the access line. The electrode may be made of a composition of a first material doped with a second material. The second material may include a tantalum-carbon compound. In some cases, the second may be operable to be chemically inert with the storage element. The second material may include a thermally stable electrical resistivity and a lower resistance to signals communicated between the access line and the storage element across a range of operating temperatures of the storage element as compared with a resistance of the first material.

A memory cell design is disclosed. In an embodiment, the memory cell structure includes at least one memory bit layer stacked between top and bottom electrodes. The memory bit layer provides a storage element for a corresponding memory cell. One or more additional conductive layers may be included between the memory bit layer and either, or both, of the top or bottom electrodes to provide a better ohmic contact. In any case, a dielectric liner structure is provided on sidewalls of the memory bit layer. The liner structure includes a dielectric layer, and may also include a second dielectric layer on a first dielectric layer. Either or both first dielectric layer or second dielectric layer comprises a high-k dielectric material. As will be appreciated, the dielectric liner structure effectively protects the memory bit layer from lateral erosion and contamination during the etching of subsequent layers beneath the memory bit layer.