Methods and structures provide horizontal conductive lines of fine pitch and self-aligned contacts extending from them, where the contacts have at least one dimension with a more relaxed pitch. Buried hard mask materials permit self-alignment of the lines and contacts without a critical mask, such as for word-line electrode lines and word-line contacts in a memory device.

The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a first resistive random access memory (RRAM) element and a second RRAM element over a substrate. A conductive element is arranged below the first RRAM element and the second RRAM element. The conductive element electrically couples the first RRAM element to the second RRAM element. An upper insulating layer continuously extends over the first RRAM element and the second RRAM element. An upper inter-level dielectric (ILD) structure laterally surrounds the first RRAM element and the second RRAM element. The upper insulating layer separates the first RRAM element and the second RRAM element from the upper ILD structure.

Methods and structures provide horizontal conductive lines of fine pitch and self-aligned contacts extending from them, where the contacts have at least one dimension with a more relaxed pitch. Buried hard mask materials permit self-alignment of the lines and contacts without a critical mask, such as for word-line electrode lines and word-line contacts in a memory device.

The disclosed technology relates generally to integrated circuit devices, and in particular to cross-point memory arrays and methods for fabricating the same. In one aspect, a memory device of the memory array comprises a substrate and a memory cell stack formed between and electrically connected to first and second conductive lines. The memory cell stack comprises a first memory element over the substrate and a second memory element formed over the first element, wherein one of the first and second memory elements comprises a storage element and the other of the first and second memory elements comprises a selector element. The memory cell stack additionally comprises a first pair of sidewalls opposing each other and a second pair of sidewalls opposing each other and intersecting the first pair of sidewalls. The memory device additionally comprises first protective dielectric insulating materials formed on a lower portion of the first pair of sidewalls and an isolation dielectric formed on the first protective dielectric insulating material and further formed on an upper portion of the first pair of sidewalls.

A thermally optimized phase change memory cell includes a phase change material element disposed between first and second electrodes. The second electrode includes a thermally insulating region having a first thermal resistivity over the first electrode and a metallic contact region interposed between the phase change material element and the thermally insulating region, where the metallic contact layer has a second thermal resistivity lower than the first thermal resistivity.

Clamp elements, memories, apparatuses, and methods for forming the same are disclosed herein. An example memory may include an array of memory cells and a plurality of clamp elements. A clamp element of the plurality of clamp elements may include a cell structure formed non-orthogonally relative to at least one of a bit line or a word line of the array of memory cells and may be configured to control a voltage of a respective bit line.

Semiconductor memory is provided wherein a memory cell includes a capacitorless transistor having a floating body configured to store data as charge therein when power is applied to the cell. The cell further includes a nonvolatile memory comprising a resistance change element configured to store data stored in the floating body under any one of a plurality of predetermined conditions. A method of operating semiconductor memory to function as volatile memory, while having the ability to retain stored data when power is discontinued to the semiconductor memory is described.

The disclosure relates to an integrated circuit comprising a transistor comprising first and second conduction terminals and a control terminal. The integrated circuit further comprises a stack of a first dielectric layer, a conductive layer, and a second dielectric layer, the first conduction terminal comprising a first semiconductor region formed in the first dielectric layer, the control terminal comprising a second semiconductor region formed in the conductive layer, and the second conduction terminal comprising a third semiconductor region formed in the second dielectric layer.

Phase change memory apparatuses include memory cells including phase change material, bit lines electrically coupled to aligned groups of at least some of the memory cells, and heating elements electrically coupled to the phase change material of the memory cells. The heating elements include vertical portions extending in a bit line direction. Additional phase change memory apparatuses include dummy columns positioned between memory columns and base contact columns. The dummy columns include phase change memory cells and lack heating elements coupled to the phase change memory cells thereof. Additional phase change memory apparatuses include heating elements operably coupled to phase change memory cells. An interfacial area between the heating elements and the phase change memory cells has a length that is independent of a bit line width. Methods relate to forming such phase change memory apparatuses.

Embodiments of the present disclosure generally relate to electronic devices, and more specifically, to multi-level phase change devices. In one embodiment, a memory cell device is provided. The memory cell device generally includes a top surface, a bottom surface and a cell body between the top surface and the bottom surface. The cell body may include a plurality of phase change material layers, which may be used to store data of the cell. In another embodiment, a method of programming a memory cell is provided. The method generally may include applying a sequence of different pulses to each phase change material layer of the cell as the voltage of each pulse in the sequence is ratcheted down from the start of a write cycle to the end of a write cycle.