Abstract: A semiconductor structure includes a first electrode, a second electrode over the first electrode, a third electrode over the second electrode, a first insulating layer between the first electrode and the second electrode, and a second insulating layer between the second electrode and the third electrode. The third electrode includes a first bottom surface and a second bottom surface. The first bottom surface and the second bottom surface are at different levels. A width of the first bottom surface is greater than a width of the second bottom surface.

Abstract: The present disclosure relates to a semiconductor device. The semiconductor device includes a first dielectric layer having a first region and a second region. A bottom electrode is at least partially arranged within the first region of the first dielectric layer. A memory element is over the bottom electrode and a top electrode is over the memory element. A second dielectric layer is over at least the first region of the first dielectric layer. The second dielectric layer surrounds the memory element and at least a part of the top electrode. A third dielectric layer is over the second region of the first dielectric layer and laterally adjacent to the second dielectric layer. A conductive interconnect is in the third dielectric layer and the second region of the first dielectric layer. The first dielectric layer has a different non-zero thickness within the first region than within the second region.

Abstract: A phase change memory device includes a first electrode, a second electrode, a phase change region, a first spacer and a second spacer. The second electrode is disposed over the first electrode. The phase change region is disposed between the first and second electrodes. The first spacer laterally covers the phase change region. The second spacer laterally covers the first spacer, and has a thermal conductivity smaller than that of the first spacer.

Abstract: Some embodiments relate to a method for forming a memory device. The method includes forming a lower dielectric layer over a conductive wire. A stack of memory layers is formed within the lower dielectric layer and over the conductive wire. The stack of memory layers comprises a top electrode, a bottom electrode, and a data storage layer between the top electrode and the bottom electrode. A removal process is performed on the stack of memory layers to define a programmable metallization cell that comprises the top electrode, the bottom electrode, and the data storage layer. The programmable metallization cell comprises a central region and a peripheral region that extends upwardly from the central region. A top surface of the programmable metallization cell and a top surface of the lower dielectric layer are coplanar.

Abstract: 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.

Abstract: A memory cell with a hard mask and a sidewall spacer of different material is provided. The memory cell may be manufactured by a method comprising forming a multi-layer stack and patterning the same to form the hard mask layer, the top electrode layer and the switching dielectric layer to form a hard mask, a top electrode and a switching dielectric. A sidewall spacer is formed alongside the hard mask, the top electrode, and the switching dielectric with a material different than the hard mask. The bottom electrode layer is patterned according to the sidewall spacer to form a bottom electrode. A dielectric layer is formed surrounding the bottom electrode, the sidewall spacer and overlying the hard mask. An etch is performed followed by a conductive material filling to form a top electrode via extending through the dielectric layer and the hard mask to reach on the top electrode.

Abstract: The present disclosure provides a semiconductor structure. The semiconductor structure includes a memory region, the memory region includes a first metal line, a magnetic tunneling junction (MTJ) over the first metal line, a cap. wherein at least a portion of the cap is above the MTJ, a first stop layer above the cap, and a first metal via being disposed over the MTJ and in direct contact with the first stop layer, and a logic region adjacent to the memory region, the logic region includes a second metal line, a third metal line over the second metal line, a second stop layer being disposed over the third metal line, and a second metal via over the third metal line.

Abstract: Various embodiments of the present application are directed towards an integrated circuit comprising a resistive random-access memory (RRAM) cell with recessed bottom electrode sidewalls to mitigate the effect of sidewall plasma damage. In some embodiments, the RRAM cell includes a lower electrode, a data storage element, and an upper electrode. The lower electrode includes a pair of recessed bottom electrode sidewalls respectively on opposite sides of the lower electrode. The data storage element overlies the lower electrode and includes a pair of storage sidewalls. The storage sidewalls are respectively on the opposite sides of the lower electrode, and the recessed bottom electrode sidewalls are laterally spaced from and laterally between the storage sidewalls. The upper electrode overlies the data storage element.

Abstract: The present disclosure provides a semiconductor structure, including an Nth metal layer, a bottom electrode over the Nth metal layer, a magnetic tunneling junction (MTJ) over the bottom electrode, a top electrode over the MTJ, and an (N+M)th metal layer over the Nth metal layer. N and M are positive integers. The (N+M)th metal layer surrounds a portion of a sidewall of the top electrode. A manufacturing method of forming the semiconductor structure is also provided.

Abstract: Some embodiments relate to a memory device. The memory device includes a top electrode overlying a bottom electrode. A data storage layer overlies the bottom electrode. The bottom electrode cups an underside of the data storage layer. The top electrode overlies the data storage layer. A top surface of the bottom electrode is aligned with a top surface of the top electrode.

Abstract: Some embodiments relate to a memory device. The memory device includes a first electrode overlying a substrate. A data storage layer overlies the first electrode. A second electrode overlies the data storage layer. A conductive bridge is selectively formable within the data storage layer to couple the first electrode to the second electrode. An active metal layer is disposed between the data storage layer and the second electrode. A buffer layer is disposed between the active metal layer and the second electrode. The buffer layer has a lower reactivity to oxygen than the active metal layer.

Abstract: A memory cell with a hard mask and a sidewall spacer of different material is provided. The memory cell comprises a bottom electrode disposed over a substrate. A switching dielectric is disposed over the bottom electrode and having a variable resistance. A top electrode is disposed over the switching dielectric. A hard mask disposed over the top electrode. A sidewall spacer extends upwardly along sidewalls of the switching dielectric, the top electrode, and the hard mask. The hard mask and the sidewall spacer have different etch selectivity. A method for manufacturing the memory cell is also provided.

Abstract: Various embodiments of the present application are directed towards an integrated circuit comprising a resistive random-access memory (RRAM) cell with recessed bottom electrode sidewalls to mitigate the effect of sidewall plasma damage. In some embodiments, the RRAM cell includes a lower electrode, a data storage element, and an upper electrode. The lower electrode includes a pair of recessed bottom electrode sidewalls respectively on opposite sides of the lower electrode. The data storage element overlies the lower electrode and includes a pair of storage sidewalls. The storage sidewalls are respectively on the opposite sides of the lower electrode, and the recessed bottom electrode sidewalls are laterally spaced from and laterally between the storage sidewalls. The upper electrode overlies the data storage element.

Abstract: Various embodiments of the present disclosure are directed towards a method for forming an integrated chip. The method includes forming a memory cell stack over a substrate. The memory cell stack includes a top electrode. A sidewall spacer structure is formed around the memory cell stack. The sidewall spacer structure includes a first sidewall spacer layer, a second sidewall spacer layer, and a protective sidewall spacer layer sandwiched between the first and second sidewall spacer layers. A dielectric structure is formed over the sidewall spacer structure. A first etch process is performed on the dielectric structure and the second sidewall spacer layer to define an opening above the top electrode. The second sidewall spacer layer and the dielectric structure are etched at a higher rate than the protective sidewall spacer layer during the first etch process. A top electrode via is formed within the opening.

Abstract: A memory device including a first array of rail structures that extend along a first horizontal direction, in which each of the rail structures are formed to serve as a bottom electrode, and a second array of rail structures that laterally extend along a second horizontal direction and are laterally spaced apart along the first horizontal direction. Each of the rail structures in the second array are formed to server as a top electrode. The memory device also includes a continuous dielectric memory layer located between the first array of rail structures and the second array of rail structures. The continuous dielectric memory layer providing protection from current leakage between the rail structures of the first array and the rail structures of the second array.

Abstract: Various embodiments of the present application are directed towards an integrated circuit comprising a resistive random-access memory (RRAM) cell with recessed bottom electrode sidewalls to mitigate the effect of sidewall plasma damage. In some embodiments, the RRAM cell includes a lower electrode, a data storage element, and an upper electrode. The lower electrode includes a pair of recessed bottom electrode sidewalls respectively on opposite sides of the lower electrode. The data storage element overlies the lower electrode and includes a pair of storage sidewalls. The storage sidewalls are respectively on the opposite sides of the lower electrode, and the recessed bottom electrode sidewalls are laterally spaced from and laterally between the storage sidewalls. The upper electrode overlies the data storage element.

Abstract: An RRAM cell stack is formed over an opening in a dielectric layer. The dielectric layer is sufficiently thick and the opening is sufficiently deep that an RRAM cell can be formed by a planarization process. The resulting RRAM cells may have a U-shaped profile. The RRAM cell area includes contributions from a bottom portion in which the RRAM cell layers are stacked parallel to the substrate and a side portion in which RRAM cell layers are stacked roughly perpendicular to the substrate. The combined side and bottom portions of the curved RRAM cell provide an increased area in comparison to a planar cell stack. The increased area lowers forming and set voltages for the RRAM cell.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a lower interconnect disposed within a dielectric structure over a substrate. A memory device includes a data storage structure disposed between a bottom electrode and a top electrode. The bottom electrode is electrically coupled to the lower interconnect. A sidewall spacer includes an interior sidewall that continuously extends from along an outermost sidewall of the top electrode to below an outermost sidewall of the bottom electrode. The sidewall spacer further includes an outermost sidewall that extends from a bottom surface of the sidewall spacer to above a top of the bottom electrode.

Abstract: The present disclosure provides a semiconductor structure, including an Nth metal layer, a bottom electrode over the Nth metal layer, a magnetic tunneling junction (MTJ) over the bottom electrode, a top electrode over the MTJ, and an (N+M)th metal layer over the Nth metal layer. N and M are positive integers. The (N+M)th metal layer surrounds a portion of a sidewall of the top electrode. A manufacturing method of forming the semiconductor structure is also provided.

Abstract: In some methods, a contact is formed over a substrate, and a bottom electrode layer is formed over the contact. A first dielectric layer is formed to cover a peripheral portion of the bottom electrode layer but not a central portion of the bottom electrode layer. A second dielectric layer is formed over the first dielectric layer. The second dielectric layer includes a central dielectric region that contacts the central portion of the bottom electrode layer, and a peripheral dielectric region over the peripheral portion of the bottom electrode. A step dielectric region connects the central and peripheral dielectric regions. A top electrode layer is formed over the second dielectric layer. The top electrode layer includes a central top electrode region, a peripheral top electrode region, and a step top electrode region directly above the central dielectric region, the peripheral dielectric region, and the step dielectric region, respectively.