Abstract: Structures and methods are provided for integrating a resistance random access memory (ReRAM) in a back-end-on-the-line (BEOL) fat wire level. In one embodiment, a ReRAM device area contact structure is provided in the BEOL fat wire level that has at least a lower via portion that contacts a surface of a top electrode of a ReRAM device area ReRAM-containing stack. In other embodiments, a tall ReRAM device area bottom electrode is provided in the BEOL fat wire level and embedded in a dielectric material stack that includes a dielectric capping layer and an interlayer dielectric material layer.

Abstract: A semiconductor device includes a ferroelectric random-access memory (FeRAM) cell. The FeRAM includes a ferroelectric dielectric that is annealed to attain its ferroelectric phase by an induced current flow and heating process. The current flow may be induced though a temporary wire that causes heating of the FeRAM cell. The resulting heating or anneal of the ferroelectric dielectric may crystalize the ferroelectric dielectric to embody or result in having ferroelectric properties. The induced current flow and heating process is substantially local to the FeRAM cell, and to ferroelectric dielectric therein, as opposed to a global heating or annealing process in which the entire semiconductor device, or a relatively larger region of semiconductor device, is heated to the requisite annealing temperature of ferroelectric dielectric.

Abstract: A porous thin film includes a framework that includes a plurality of pores. The pores extend from an opening located at an upper surface of the framework to a bottom surface contained in the framework. A pore-coating film is formed on sidewalls and the bottom surface of the pores.

Abstract: A method for mitigating moisture driven degradation of silicon doped chalcogenides includes placing a silicon doped chalcogenide composition in a process chamber, passivating dangling silicon bonds of the silicon doped chalcogenide composition by flooding the process chamber with forming gas or with hydrogen plasma, purging the forming gas or the hydrogen plasma from the process chamber, and removing the passivated silicon doped chalcogenide composition from the process chamber.

Abstract: Embodiments of process flows and methods are provided for forming a resistive switching random access memory (ReRAM). More specifically, process flows and methods are provided for reducing the forming voltage needed to form a conductive path in the ReRAM cells. A wide variety of plasma doping processes are used to introduce a plurality of different dopants into a metal-oxide dielectric film. By utilizing at least two different dopants, the plasma doping processes described herein reduce the forming voltage of the subsequently formed ReRAM cell compared to conventional processes that use only one dopant. In some embodiments, the forming voltage may be further reduced by applying a bias power during the plasma doping process, wherein the bias power is preselected to increase the number of ions introduced into the metal-oxide dielectric film during the plasma doping process.

Abstract: A resistive memory device with an embedded shoulder pulled sidewall spacer and method of forming. The method includes providing a patterned film stack containing a lower electrode layer, a dielectric filament layer on the lower electrode layer, and an upper electrode layer on the dielectric filament layer, depositing a conformal cap layer on the patterned film stack, dry etching the conformal cap layer to form a sidewall spacer on sidewalls of the patterned film stack, where a top of the sidewall spacer is recessed to below a top of the upper electrode layer by the dry etching. The method further includes encapsulating the patterned film stack in an isolation layer, and etching the isolation layer to expose the upper electrode layer without exposing the sidewall spacer.

Abstract: Techniques facilitating resistive random-access memory device with step height difference are provided. A resistive random-access memory device can comprise a first electrode located within a trench of a dielectric layer. The resistive random-access memory device can also comprise a metal oxide layer comprising a first section located within the trench of the dielectric layer, and a second section located over the first electrode, and over a barrier metal layer. Further, the resistive random-access memory device can comprise a second electrode located over the metal oxide layer.

Abstract: Embodiments of the invention provide a resistive switching device that includes a metal interconnect electrode and a memory stack over the metal interconnect electrode. The memory stack includes a plurality of layers that includes a top electrode, a plasma-treated bottom electrode, and a dielectric layer between the top electrode and the plasma-treated bottom electrode. The plasma-treated bottom electrode includes a portion of a blanket bottom electrode layer. The plasma-treated bottom electrode further includes a current-conducting filament characteristic that results from a charge particle treatment applied to the blanket bottom electrode while a top surface of the blanket bottom electrode is exposed.

Abstract: Techniques facilitating resistive random-access memory device with step height difference are provided. A resistive random-access memory device can comprise a first electrode located within a trench of a dielectric layer. The resistive random-access memory device can also comprise a metal oxide layer comprising a first section located within the trench of the dielectric layer, and a second section located over the first electrode, and over a barrier metal layer. Further, the resistive random-access memory device can comprise a second electrode located over the metal oxide layer.

Abstract: A resistive memory includes: a bottom electrode; a first contact on the bottom electrode; a switching material pad on the first contact, wherein the switching material pad includes an oxide and a plurality of current conducting filaments in the oxide; a top electrode on the switching material pad; a plurality of sacrificial vias contacting the bottom electrode; a second contact that is connected to the bottom electrode; and a third contact that is connected to the top electrode.

Abstract: A semiconductor structure comprises a conductive bridge random access memory device and an access device connected in series with the conductive bridge random access memory device. The conductive bridge random access memory device and the access device are arranged in a vertical stack. The vertical stack has a sidewall profile that increases in width from a bottom surface of the vertical stack to a top surface of the vertical stack.

Abstract: A method of fabricating a resistive semiconductor memory structure that provides in-situ selective etch of phase change materials during deposition of dielectric at low temperature (in the same chamber). The method provides, to a single processing chamber, a semiconductor wafer including a trimmed resistive memory device structure having one or more layers of phase change material used to form a resistive memory device. The one or more layers of phase change material have oxidized sidewall surfaces as a result of a prior etching step where a whole stack structure of the layers forming the resistive memory structure is etched. Then, an encapsulating of the trimmed resistive memory device structure is performed by depositing, within the processing chamber, using a PECVD, a layer of dielectric material, and during the encapsulating, etching, within the processing chamber, the wafer to selectively remove the phase change material oxidation at the sidewall surfaces.

Abstract: Provided are embodiments for a semiconductor device. The semiconductor device includes a bottom electrode, wherein the bottom electrode is formed on a metal interconnect electrode, and a dielectric layer on a surface of the bottom electrode. The semiconductor device also includes a top electrode formed on a surface of the dielectric layer, wherein at least one of the top electrode or the bottom electrode is a plasma treated top electrode or plasma treated bottom electrode. Also provided are embodiments for a method of fabricating a resistive switching device where at least one of the plurality of layers of the memory stack is processed with a charge particle treatment.

Abstract: A method for manufacturing a semiconductor memory device includes depositing a bottom metal line layer on a dielectric layer, and patterning the bottom metal line layer into a plurality of bottom metal lines spaced apart from each other. In the method, a plurality of switching element dielectric portions are formed on respective ones of the plurality of bottom metal lines, and a top metal line layer is deposited on the plurality of switching element dielectric portions. The method further includes patterning the top metal line layer into a plurality of top metal lines spaced apart from each other. The plurality of top metal lines are oriented perpendicular to the plurality of bottom metal lines.

Abstract: A porous thin film includes a framework that includes a plurality of pores. The pores extend from an opening located at an upper surface of the framework to a bottom surface contained in the framework. A pore-coating film is formed on sidewalls and the bottom surface of the pores.

Abstract: Structures and methods are provided for integrating a resistance random access memory (ReRAM) in a back-end-on-the-line (BEOL) fat wire level. In one embodiment, a ReRAM device area contact structure is provided in the BEOL fat wire level that has at least a lower via portion that contacts a surface of a top electrode of a ReRAM device area ReRAM-containing stack. In other embodiments, a tall ReRAM device area bottom electrode is provided in the BEOL fat wire level and embedded in a dielectric material stack that includes a dielectric capping layer and an interlayer dielectric material layer.

Abstract: Embodiments of process flows and methods are provided for forming a resistive switching random access memory (ReRAM). More specifically, process flows and methods are provided for reducing the forming voltage needed to form a conductive path in the ReRAM cells. A wide variety of plasma doping processes are used to introduce a plurality of different dopants into a metal-oxide dielectric film. By utilizing at least two different dopants, the plasma doping processes described herein reduce the forming voltage of the subsequently formed ReRAM cell compared to conventional processes that use only one dopant. In some embodiments, the forming voltage may be further reduced by applying a bias power during the plasma doping process, wherein the bias power is preselected to increase the number of ions introduced into the metal-oxide dielectric film during the plasma doping process.

Abstract: A low voltage forming NVM structure including a plurality of ReRAM devices arranged in a cross bar array and sandwiched between a plurality of first electrically conductive structures and a plurality of second electrically conductive structures. Each first electrically conductive structure is oriented perpendicular to each second electrically conductive structure. The plurality of second electrically conductive structures includes a first set of second electrically conductive structures having a first top trench area A1, and a second set of second electrically conductive structures having a second top trench area A2 that is greater than A1. Each second electrically conductive structure of the first set contacts a surface of at least one of the first electrically conductive structures, and each second electrically conductive structure of the second set contacts a top electrode of at least one of the ReRAM devices.

Abstract: A method for manufacturing a semiconductor memory device includes depositing a bottom metal line layer on a dielectric layer, and patterning the bottom metal line layer into a plurality of bottom metal lines spaced apart from each other. In the method, a plurality of switching element dielectric portions are formed on respective ones of the plurality of bottom metal lines, and a top metal line layer is deposited on the plurality of switching element dielectric portions. The method further includes patterning the top metal line layer into a plurality of top metal lines spaced apart from each other. The plurality of top metal lines are oriented perpendicular to the plurality of bottom metal lines.

Abstract: A method for mitigating moisture driven degradation of silicon doped chalcogenides includes placing a silicon doped chalcogenide composition in a process chamber, passivating dangling silicon bonds of the silicon doped chalcogenide composition by flooding the process chamber with forming gas or with hydrogen plasma, purging the forming gas or the hydrogen plasma from the process chamber, and removing the passivated silicon doped chalcogenide composition from the process chamber.