Abstract: A phase change memory (PCM) cell having a mushroom configuration includes a first electrode, a heater electrically connected to the first electrode, a first projection liner electrically connected to the heater, a PCM material electrically connected to the first projection liner, a second electrode electrically connected to the PCM material, and a second projection liner electrically connected to the first projection liner and the second electrode.

Abstract: Insulated phase change memory devices are provided that include a first electrode; a second electrode; a phase change material disposed in an electrical path between the first electrode and the second electrode; and a porous dielectric configured to concentrate heat produced by a reset current carried through the phase change material between the first electrode and the second electrode to mitigate an amount of heat that escapes from the phase change material. The porous dielectric may be an inherently porous dielectric material or a dielectric material in which porous structures are induced during fabrication. Methods of fabrication of such devices are also provided.

Abstract: A semiconductor structure includes a heater located in a first layer of a device, wherein the heater is surrounded by a dielectric, a phase change memory (PCM) liner in direct contact with a top surface of the heater in a second layer of the device, a spacer disposed adjacent the PCM liner in the second layer of the device, and a PCM stack disposed above the PCM liner in the second layer of the device.

Abstract: A vertical resistive memory array is presented. The array includes a pillar electrode and a switching liner around the side perimeter of the pillar electrode. The array includes two or more vertically stacked single cell (SC) electrodes connected to a first side of the switching liner. The juxtaposition of the switching liner, the pillar electrode, and each SC electrode forms respective resistance switching cells (e.g., OxRRAM cell). A vertical group or bank of these cells may be connected in parallel and each share the same pillar electrode. The cells in the vertical cell bank may written to or read from as a group to limit the effects of inconsistent CF formation of any one or more individual cells within the group.

Abstract: A heater, a system, and a method for linearly changing the resistance of the phase change memory through a graded heater. The system may include a phase change memory. The phase change memory may include a dielectric. The phase change memory may also include a heater patterned on the dielectric, the heater including: an outside conductive heating layer that has a higher resistance than other layers of the heater, and an inside conductive heating layer that has a lower resistance than the outside conductive heating layer, where the outside conductive heating layer is at an outside area of the heater and the inside conductive heating layer is at an inside area of the heater. The phase change memory may also include a phase change material proximately connected to the heater. The phase change memory may also include a top electrode proximately connected to the phase change material.

Abstract: A method for fabricating a semiconductor device includes forming a first line pattern within sacrificial mandrel material disposed on at least one hard mask layer disposed on a substrate. The first line pattern has a pitch defined by a target line width and a minimum width of space between lines. The method further includes forming, within the first line pattern, a first spacer having a width corresponding to the minimum width of space between lines to minimize pinch points and a first gap having the target line width, and forming a first plug within the first gap corresponding to a first location above the at least one hard mask layer to block pattern transfer into the at least one hard mask layer.

Abstract: An embodiment of the invention may include a semiconductor structure. The semiconductor structure may include a phase change element located above a heater. The heater may include a conductive element surrounding a dielectric element. The dielectric element may include an air gap.

Abstract: Devices, systems, and/or methods that can facilitate topological quantum computing are provided. According to an embodiment, a device can comprise a circuit layer formed on a wiring layer of the device and that comprises control components. The device can further comprise a topological qubit device formed on the circuit layer and that comprises a nanorod capable of hosting Majorana fermions and a quantum well tunable Josephson junction that is coupled to the control components.

Abstract: A phase change memory (PCM) cell comprises a first electrode comprised of a first electrically conductive material, a second electrode comprised of a second electrically conductive material, a first phase change layer positioned between the first electrode and the second electrode and being comprised of a first phase change material, and a second phase change layer positioned between the first electrode and the second electrode and being comprised of a second phase change material. The first phase change material has a first resistivity, the second phase change material has a second resistivity, and wherein the first resistivity is at least two times the second resistivity.

Abstract: An apparatus comprising a dielectric layer located between a first electrode and a second electrode and a third electrode located on the dielectric layer between the first electrode and the electrode, wherein the first electrode is separated from a first side of the third electrode by a first portion of the dielectric layer, and the second electrode is separated from a second side of the third electrode by a second portion of the dielectric layer.

Abstract: A non-volatile memory structure may include a phase change memory comprising a phase change material. The non-volatile memory structure may include a Schottky diode in series with the phase change memory, wherein a Schottky barrier of the Schottky diode is a surface of the phase change memory. This may be accomplished through a proper selection of materials for the contact of the phase change memory. This may create an integrated diode-memory structure which may control directionality of current without a penalty on the footprint of the structure.

Abstract: A vertical resistive memory array is presented. The array includes a pillar electrode and a switching liner around the side perimeter of the pillar electrode. The array includes two or more vertically stacked single cell (SC) electrodes connected to a first side of the switching liner. The juxtaposition of the switching liner, the pillar electrode, and each SC electrode forms respective resistance switching cells (e.g., OxRRAM cell). A vertical group or bank of these cells may be connected in parallel and each share the same pillar electrode. The cells in the vertical cell bank may written to or read from as a group to limit the effects of inconsistent CF formation of any one or more individual cells within the group.

Abstract: A memory device enabling a reduced minimal conductance state may be provided. The device comprises a first electrode, a second electrode and phase-change material between the first electrode and the second electrode, wherein the phase-change material enables a plurality of conductivity states depending on the ratio between a crystalline and an amorphous phase of the phase-change material. The memory device comprises additionally a projection layer portion in a region between the first electrode and the second electrode. Thereby, an area directly covered by the phase-change material in the amorphous phase in a reset state of the memory device is larger than an area of the projection layer portion oriented to the phase-change material, such that a discontinuity in the conductance states of the memory device is created and a reduced minimal conductance state of the memory device in a reset state is enabled.

Abstract: A method of forming a phase change memory device is provided. The method includes forming a spacer layer on a substrate, and forming a heater terminal contact in the spacer layer. The method further includes forming a liner layer on the heater terminal contact and the spacer layer, and forming a heater terminal in electrical contact with the heater terminal contact in the liner layer. The method further includes forming a conductive projection segment on the heater terminal. The method further includes forming a phase change material layer on the conductive projection segment, and forming a phase change material terminal on the phase change material layer, wherein an electrical current can pass between the heater terminal and the phase change material terminal through the phase change material layer.

Abstract: A method includes forming a plurality of elongated dielectric members on a semiconductor substrate. The elongated dielectric members each extend vertically from the semiconductor substrate and define opposed vertical walls. The method further includes forming opposed spacer walls on the vertical walls of the elongated dielectric members. Adjacent spacer walls of longitudinally adjacent elongated dielectric members define first trenches therebetween. The method also includes depositing a first metal material within the first trenches to form a first set of first metal lines, removing the elongated dielectric members to define second trenches between the opposed spacer walls on the opposed vertical walls of each elongated dielectric member, and depositing a second metal material within the second trenches to form a second set of second metal lines. The first and second metal lines of the first and second sets are disposed in alternating arrangement.

Abstract: A method includes forming a dielectric layer on a semiconductor substrate, forming a first mandrel layer and a second mandrel layer on the dielectric layer and patterning the first mandrel layer and the second mandrel layer to form respective first and second patterns in the first and second mandrel layers. The first pattern includes a first line segment and a first wing segment. The first wing segment is filled with a first spacer material to form a first spacer. The method further includes removing exposed portions of the first and second mandrel layers, transferring an image of the first and second patterns, patterning the dielectric layer and depositing a metal into the patterned dielectric layer to form a metallic interconnect structure. The metallic interconnect structure includes first and second metallic lines with the second metallic line having a line break corresponding to the first spacer.

Abstract: A method includes forming a dielectric layer on a semiconductor substrate, forming a hard mask layer on the dielectric layer, forming a sacrificial mandrel layer on the hard mask layer, depositing a sacrificial fill material in an opening in the sacrificial mandrel layer and utilizing the sacrificial fill material to selectively pattern the hard mask layer. The pattern defining first and second spaced openings in the hard mask layer. The method further includes etching the dielectric layer through the first and second openings in the hard mask layer to create first and second trenches in the dielectric layer separated by a dielectric segment of the dielectric layer.

Abstract: A multiterminal non-volatile memory cross-bar array system includes a set of conductive row rails, a set of conductive column rails configured to form a plurality of crosspoints at intersections between the conductive rails and the conductive column rails and a resistive processing unit at each of the crosspoints each representing a neuron in a neural network. At least one given conductive row rail includes first and second row lines is in contact with a given resistive processing unit. At least one given conductive column rail including first and second column lines is in contact with the given resistive processing unit.

Abstract: A method of forming a phase change memory device is provided. The method includes forming a spacer layer on a substrate, and forming a heater terminal contact in the spacer layer. The method further includes forming a liner layer on the heater terminal contact and the spacer layer, and forming a heater terminal in electrical contact with the heater terminal contact in the liner layer. The method further includes forming a conductive projection segment on the heater terminal. The method further includes forming a phase change material layer on the conductive projection segment, and forming a phase change material terminal on the phase change material layer, wherein an electrical current can pass between the heater terminal and the phase change material terminal through the phase change material layer.

Abstract: A method includes forming a dielectric layer on a semiconductor substrate, forming a first mandrel layer and a second mandrel layer on the dielectric layer and patterning the first mandrel layer and the second mandrel layer to form respective first and second patterns in the first and second mandrel layers. The first pattern includes a first line segment and a first wing segment. The first wing segment is filled with a first spacer material to form a first spacer. The method further includes removing exposed portions of the first and second mandrel layers, transferring an image of the first and second patterns, patterning the dielectric layer and depositing a metal into the patterned dielectric layer to form a metallic interconnect structure. The metallic interconnect structure includes first and second metallic lines with the second metallic line having a line break corresponding to the first spacer.