A semiconductor memory device includes a substrate, a first dielectric layer on the substrate, a bottom electrode on the first dielectric layer, a second dielectric layer on the first dielectric layer, and a top electrode in the second dielectric layer. The top electrode has a lower portion around the bottom electrode and a tapered upper portion. A third dielectric layer is disposed above the bottom electrode and around the tapered upper portion of the top electrode. A resistive-switching layer is disposed between a sidewall of the bottom electrode and a sidewall of the lower portion of the top electrode and between the third dielectric layer and a sidewall of the tapered upper portion of the top electrode. An air gap is disposed in the third dielectric layer.

A method of manufacturing a variable resistance memory device may include: forming a memory cell including a variable resistance pattern on a substrate; performing a first process to deposit a first protective layer covering the memory cell; and performing a second process to deposit a second protective layer on the first protective layer. The first process and the second process may use the same source material and the same nitrogen reaction material, and a nitrogen content in the first protective layer may be less than a nitrogen content in the second protective layer.

Resistive memory having confined filament formation is described herein. One or more method embodiments include forming an opening in a stack having a silicon material and an oxide material on the silicon material, and forming an oxide material in the opening adjacent the silicon material, wherein the oxide material formed in the opening confines filament formation in the resistive memory cell to an are enclosed by the oxide material formed in the opening.

A method of forming a semiconductor structure includes depositing a first electrode material over a conductive structure and a dielectric layer, patterning the first electrode material to form a first electrode contacting the conductive structure, depositing a resistance variable layer over the first electrode and the dielectric layer, depositing a second electrode material over the resistance variable layer, and etching a portion of the second electrode material and the resistance variable layer to form a second electrode over a remaining portion of the resistance variable layer.

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 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.

According to one embodiment, a magnetic memory device includes a stacked structure including a first magnetic layer, a second magnetic layer and a nonmagnetic layer between the first magnetic layer and the second magnetic layer, and a sidewall insulating layer provided on a side surface of the stacked structure and containing boron (B).

Some embodiments include methods of forming structures. Spaced-apart features are formed which contain temperature-sensitive material. Liners are formed along sidewalls of the features under conditions which do not expose the temperature-sensitive material to a temperature exceeding 300° C. The liners extend along the temperature-sensitive material and narrow gaps between the spaced-apart features. The narrowed gaps are filled with flowable material which is cured under conditions that do not expose the temperature-sensitive material to a temperature exceeding 300° C. In some embodiments, the features contain memory cell regions over select device regions. The memory cell regions include first chalcogenide and the select device regions include second chalcogenide. The liners extend along and directly against the first and second chalcogenides.

Various embodiments of the present application are directed towards an integrated chip. The integrated chip includes an array overlying a substrate and including multiple memory stacks in a plurality of rows and a plurality of columns. Each of the memory stacks includes a data storage structure having a variable resistance. A plurality of word lines are disposed beneath the array and extend along corresponding rows of the array. The word lines are electrically coupled with memory stacks of the array in the corresponding rows. A plurality of upper conductive vias extend from above the array of memory stacks to contact top surfaces of corresponding word lines.

A memory device and method of forming the same are provided. The memory device includes a first memory cell disposed over a substrate. The first memory cell includes a transistor and a data storage structure coupled to the transistor. The transistor includes a gate pillar structure, a channel layer laterally wrapping around the gate pillar structure, a source electrode surrounding the channel layer, and a drain electrode surrounding the channel layer. The drain electrode is separated from the source electrode a dielectric layer therebetween. The data storage structure includes a data storage layer surrounding the channel layer and sandwiched between a first electrode and a second electrode. The drain electrode of the transistor and the first electrode of the data storage structure share a common conductive layer.