Abstract: A semiconductor arrangement includes an active region including a semiconductor device. The semiconductor arrangement includes a capacitor. The capacitor includes a first electrode over at least one dielectric layer over the active region. The first electrode surrounds an open space within the capacitor. The first electrode has a non-linear first electrode sidewall.

Abstract: Various embodiments provide a flash memory with an improved gate structure and a method of creating the same. The flash memory includes a plurality of memory cells that include a memory gate, a selection gate, a gate dielectric layer, and a protective cap formed on an upper surface of the gate dielectric layer. The protective cap protects the gate dielectric layer, and prevents the memory and selection gates from being unintentionally electrically connected to each other by conductive material.

Abstract: Pillar stacks of a top electrode and a hard mask portion are formed over a layer stack containing a continuous reference magnetization layer, a continuous nonmagnetic tunnel barrier layer, and a continuous free magnetization layer. A continuous dielectric liner may be deposited and anisotropically etched to form inner dielectric spacers. The continuous free magnetization layer, the continuous nonmagnetic tunnel barrier layer, and the continuous reference magnetization layer may be anisotropically etched to form vertical stacks of a respective reference magnetization layer, a respective nonmagnetic tunnel barrier layer, and a respective free magnetization layer, which are magnetic tunnel junctions. The inner dielectric spacers prevent redeposition of a metallic material of the hard mask portions on sidewalls of the magnetic tunnel junctions. The hard mask portions may be removed, and a metallic cell contact structures may be formed on top of each top electrode.

Abstract: A phase change memory (PCM) cell with a low deviation contact area between a heater and a phase change element is provided. The PCM cell comprises a bottom electrode, a dielectric layer, a heater, a phase change element, and a top electrode. The dielectric layer overlies the bottom electrode. The heater extends upward from the bottom electrode, through the dielectric layer. Further, the heater has a top surface that is substantially planar and that is spaced below a top surface of the dielectric layer. The phase change element overlies the dielectric layer and protrudes into the dielectric layer to contact with the top surface of the heater. Also provided is a method for manufacturing the PCM cell.

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: A semiconductor structure includes an Nth metal layer, a diffusion barrier layer over the Nth metal layer, a first deposition of bottom electrode material over the diffusion barrier layer, a second deposition of bottom electrode material over the first deposition of bottom electrode material, a magnetic tunneling junction (MTJ) layer over the second deposition of bottom electrode material, a top electrode over the MTJ layer; and an (N+1)th metal layer over the top electrode; wherein the diffusion barrier layer and the first deposition of bottom electrode material are laterally in contact with a dielectric layer, the first deposition of bottom electrode material spacing the diffusion barrier layer and the second deposition of bottom electrode material apart, and N is an integer greater than or equal to 1. An associated electrode structure and method are also disclosed.

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: A memory cell with hard mask insulator and its manufacturing methods are provided. In some embodiments, a memory cell stack is formed over a substrate having a bottom electrode layer, a resistance switching dielectric layer over the bottom electrode layer, and a top electrode layer over the resistance switching dielectric layer. A first insulating layer is formed over the top electrode layer. A first metal hard masking layer is formed over the first insulating layer. Then, a series of etch is performed to pattern the first metal hard masking layer, the first insulating layer, the top electrode layer and the resistance switching dielectric layer to form a first metal hard mask, a hard mask insulator, a top electrode, and a resistance switching dielectric.

Abstract: Various embodiments provide a flash memory with an improved gate structure and a method of creating the same. The flash memory includes a plurality of memory cells that include a memory gate, a selection gate, a gate dielectric layer, and a protective cap formed on an upper surface of the gate dielectric layer. The protective cap protects the gate dielectric layer, and prevents the memory and selection gates from being unintentionally electrically connected to each other by conductive material.

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.

Abstract: A semiconductor arrangement is provided comprising a guard region. The semiconductor arrangement comprises an active region disposed on a first side of the guard region. The active region comprises an active device. The guard region of the semiconductor arrangement comprises residue from the active region. A method of forming a semiconductor arrangement is also provided.

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: An integrated circuits device includes a semiconductor substrate having a logic region and a memory region separated by an isolation region having an isolation structure of dielectric material. A memory device is formed on the memory region and includes a gate electrode over a gate dielectric. A dummy gate structure is formed on the isolation structure. The dummy gate structure has a dummy gate electrode layer corresponding to the gate electrode and a dummy gate dielectric layer corresponding to the gate dielectric. A tapered sidewall structure is formed on a logic region-facing side of the dummy gate structure. The tapered sidewall structure is spaced above the isolation structure and either adjacent to or contiguous with the dummy gate electrode layer.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes: a substrate and a gate element over the substrate. The gate element includes: a gate dielectric layer over the substrate; a gate electrode over the gate dielectric layer; and a waveguide passing through the gate electrode from a top surface of the gate electrode to a bottom surface of the gate electrode. A manufacturing method of the same is also disclosed.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a source/drain region arranged within a substrate. A first select gate is arranged over the substrate, and a first memory gate is arranged over the substrate and separated from the source/drain region by the first select gate. An inter-gate dielectric structure is arranged between the first memory gate and the first select gate. The inter-gate dielectric structure extends under the first memory gate. A height of the inter-gate dielectric structure decreases along a direction extending from the first select gate to the first memory gate.

Abstract: The present disclosure provides a semiconductor structure. The semiconductor structure includes a transistor layer, a memory region over the transistor layer, and a logic region adjacent to the memory region. The memory region includes a first Nth metal line, a magnetic tunneling junction (MTJ) over the first Nth metal line, a cap over the MTJ, a first stop layer on the cap, and a first (N+1)th metal via over the MTJ. The first (N+1)th metal via is laterally surrounded by the cap and the first stop layer. The logic region includes a second Nth metal line, a second stop layer over an (N+1)th metal line, and a second (N+1)th metal via over the (N+1)th metal line. N is an integer greater than or equal to 1.

Abstract: Various embodiments of the present application are directed towards a semiconductor device comprising a trench capacitor, the trench capacitor comprising a plurality of lateral protrusions. In some embodiments, the trench capacitor comprises a dielectric structure over a substrate. The dielectric structure may comprise a plurality of dielectric layers overlying the substrate. The dielectric structure may comprise a plurality of lateral recesses. In some embodiments, the plurality of lateral protrusions extend toward and fill the plurality of lateral recesses. By forming the trench capacitor with the plurality of lateral protrusions filling the plurality of lateral recesses, the surface area of the capacitor is increased without increasing the depth of the trench. As a result, greater capacitance values may be achieved without necessarily increasing the depth of the trench and thus, without necessarily increasing the size of the semiconductor device.

Abstract: A semiconductor structure includes an Nth metal layer, a diffusion barrier layer over the Nth metal layer, a first deposition of bottom electrode material over the diffusion barrier layer, a second deposition of bottom electrode material over the first deposition of bottom electrode material, a magnetic tunneling junction (MTJ) layer over the second deposition of bottom electrode material, a top electrode over the MTJ layer; and an (N+1)th metal layer over the top electrode; wherein the diffusion barrier layer and the first deposition of bottom electrode material are laterally in contact with a dielectric layer, the first deposition of bottom electrode material spacing the diffusion barrier layer and the second deposition of bottom electrode material apart, and N is an integer greater than or equal to 1. An associated electrode structure and method are also disclosed.

Abstract: A semiconductor arrangement includes a logic region and a memory region. The memory region has an active region that includes a semiconductor device. The memory region also has a capacitor within one or more dielectric layers over the active region, where the capacitor is over the semiconductor device. The semiconductor arrangement also includes a protective ring within at least one of the logic region or the memory region and that separates the logic region from the memory region. The capacitor has a first electrode, a second electrode and an insulating layer between the first electrode and the second electrode, where the first electrode is substantially larger than other portions of the capacitor.