Abstract: Three dimensional memory array architectures and methods of forming the same are provided. An example memory array can include a stack comprising a plurality of first conductive lines at a number of levels separated from one another by at least an insulation material, and at least one conductive extension arranged to extend substantially perpendicular to the plurality of first conductive lines. Storage element material is formed around the at least one conductive extension. Cell select material is formed around the at least one conductive extension. The at least one conductive extension, storage element material, and cell select material are located between co-planar pairs of the plurality of first conductive lines.

Abstract: In a fabrication process for reversible resistance-switching memory cells, a bottom electrode layer is coated with nano-particles. The nano-particles are used to etch the bottom electrode layer, forming multiple narrow, spaced apart bottom electrode structures for each memory cell. A resistance-switching material is then deposited between and above the bottom electrode structures, followed by a top electrode layer. Or, insulation is deposited between and above the bottom electrode structures, followed by planarizing and a wet etch to expose top surfaces of the bottom electrode structures, then deposition of the resistance-switching material and the top electrode layer. When the resistance state of the memory cell is switched, there is a smaller area in the bottom electrode for a current path, so the switching resistance is higher and the switching current is lower.

Abstract: A programmable metallization device comprises a first electrode and a second electrode, and a dielectric layer, a conductive ion-barrier layer, and an ion-supplying layer in series between the first and second electrodes. In operation, a conductive bridge is formed or destructed in the dielectric layer to represent a data value using bias voltages having the same polarity, enabling the use of diode access devices. To form a conductive bridge, a bias is applied that is high enough to cause ions to penetrate the conductive ion-barrier layer into the dielectric layer, which then form filaments or bridges. To destruct the conductive bridge, a bias of the same polarity is applied that causes current to flow through the structure, while ion flow is blocked by the conductive ion-barrier layer. As a result of Joule heating, any bridge in the dielectric layer disintegrates.

Abstract: A phase change memory device includes a phase change memory unit and a heat sink. The phase change memory unit includes a phase change material layer pattern, a lower electrode beneath the phase change material layer pattern configured to heat the phase change material layer pattern, and an upper electrode on the phase change material layer pattern. The heat sink configured to absorb heat from the phase change memory unit. The heat sink has a top surface lower than a top surface of the upper electrode and is spaced apart from the phase change memory unit.

Abstract: The present invention discloses an organic resistive random access memory and a preparation method thereof. The memory uses silicon as a substrate, and has a MIM capacitor structure having a vertical memory unit, where the MIM structure has a top electrode of Al, a bottom electrode of ITO, and an middle functional layer of parylene, wherein, a parylene layer as the functional layer is formed by performing deposition multiple times, where the deposition of Al2O3 is performed once by ALD between each two deposition of parylene. A critical region which is in favor of forming a conductive channel could be formed by controlling the deposition area of Al2O3, and further control the electrical characteristics of the memory. Through the present invention, the cycle-to-cycle and device-to-device uniformity could be effectively improved, without changing the basic structure of the memory.

Abstract: Some embodiments include a memory cell having a pair of electrodes, and a plurality of switching levels between the electrodes. Each switching level has an ion buffer region and a dielectric region. At least one switching level differs from another switching level in one or both of thickness and composition of the ion buffer region and/or the dielectric region.

Abstract: The present disclosure includes a high density resistive random access memory (RRAM) device, as well as methods of fabricating a high density RRAM device. One method of forming an RRAM device includes forming a resistive element having a metal-metal oxide interface. Forming the resistive element includes forming an insulative material over the first electrode, and forming a via in the insulative material. The via is conformally filled with a metal material, and the metal material is planarized to within the via. A portion of the metal material within the via is selectively treated to create a metal-metal oxide interface within the via. A second electrode is formed over the resistive element.

Abstract: A storage element can include a bottom structure having at least one edge formed by a top surface and a side surface; a programmable layer, programmable between at least two different impedance states, and formed over the at least one edge and in contact with a portion of the bottom structure; an insulating layer that extends above the top surface of the bottom structure having an opening to the bottom structure formed therein, the opening having sloped sides; and at least one top layer formed within the opening and in contact with the programmable layer. Methods of making such a storage element are also disclosed.

Abstract: According to one embodiment, a memory device includes a first electrode, a second electrode and a variable resistance layer. The second electrode includes a metal. The metal is more easily ionizable than a material of the first electrode. The variable resistance layer is disposed between the first electrode and the second electrode. The variable resistance layer includes a first layer and a second layer. The first layer has a relatively high crystallization rate. The second layer contacts the first layer. The second layer has a relatively low crystallization rate. The first layer and the second layer are stacked along a direction connecting the first electrode and the second electrode.

Abstract: According to one embodiment, a nonvolatile resistance change element includes a first electrode, a second electrode, a first layer and a second layer. The second electrode contains at least one metal element selected from Ag, Cu, Ni, Co, Al, and Ti. The first layer is arranged between the first electrode and the second electrode. The second layer is arranged between the first electrode and the first layer. A diffusion coefficient of the metal element in the second layer is larger than a diffusion coefficient of the metal element in the first layer.

Abstract: Providing for fabrication, construction, and/or assembly of a resistive random access memory (RRAM) cell is described herein. The RRAM cell can exhibit a non-linear current-voltage relationship. When arranged in a memory array architecture, these cells can significantly mitigate sneak path issues associated with conventional RRAM arrays.

Abstract: A RRAM device having a diode device structure coupled to a variable resistance layer is disclosed. The diode device structure can either be embedded into or fabricated over the substrate. A memory device having an array of said RRAM devices can be fabricated with multiple common bit lines and common word lines.

Abstract: Selector devices that can be suitable for memory device applications can have low leakage currents at low voltages to reduce sneak current paths for non selected devices, and high leakage currents at high voltages to minimize voltage drops during device switching. In some embodiments, the selector device can include a first electrode, a tri-layer dielectric layer, and a second electrode. The tri-layer dielectric layer can include a high leakage dielectric layer sandwiched between two lower leakage dielectric layers. The low leakage layers can function to restrict the current flow across the selector device at low voltages. The high leakage dielectric layer can function to enhance the current flow across the selector device at high voltages.

Abstract: A stack of layers defines a filter and is formed by copper on hydrogenated silicon nitride supported by a carrier. The filter includes a layer of hydrogenated silicon nitride, a layer of silicon oxide on the layer of hydrogenated silicon nitride and a layer of copper on the layer of silicon oxide. The layer of hydrogenated silicon nitride may have, in a vicinity of its upper side, a ratio of a number of silicon atoms per cubic centimeter to a number of nitrogen atoms per cubic centimeter lower than 0.8 (or even lower than 0.6), with a number of silicon-hydrogen bonds smaller than or equal to 6×1021 bonds per cubic centimeter (or even smaller than 0.5×1021 bonds per cubic centimeter). The filter further includes an additional layer of copper between the layer of hydrogenated silicon nitride and the carrier.

Abstract: The purpose of the present invention is to provide a semiconductor storage device, which has small resistance in the ON state, and a small leak current in the OFF state, and which has a small-sized select transistor used therein. In this semiconductor storage device, a channel of a first select transistor that selects a memory cell array is electrically connected to each of the adjacent memory cell arrays (see FIG. 1).

Abstract: Provided is an electronic device including a semiconductor memory. The semiconductor memory includes a first metal oxide layer disposed over a substrate and including a trench therein, a second metal oxide layer disposed along an inner wall of the trench, a selector disposed over the second metal oxide layer and buried in a part of the trench, and a top electrode disposed over the selector.

Abstract: The present disclosure includes memory cell structures and method of forming the same. One such memory cell includes a first electrode having sidewalls angled less than 90 degrees in relation to a bottom surface of the first electrode, a second electrode, including an electrode contact portion of the second electrode, having sidewalls angled less than 90 degrees in relation to the bottom surface of the first electrode, wherein the second electrode is over the first electrode, and a storage element between the first electrode and the electrode contact portion of the second electrode.

Abstract: A phase change memory structure, including a substrate having a cavity extending from a surface of the substrate into an interior region thereof, wherein the cavity is bounded by side wall surface, wherein the cavity is coated on the side wall surface with a film of phase change memory material defining a core that is at least partially filled with dielectric material such as alumina. Such phase change memory structure can be fabricated in a substrate containing a cavity closed at one end thereof with a bottom electrode, by a method including: conformally coating sidewall surface of the cavity and surface of the bottom electrode closing the cavity, with a phase change memory material film, to form an open core volume bounded by the phase change memory material film; at least partially filling the open core volume with alumina or other dielectric material; and forming a top electrode at an upper portion of the cavity.

Abstract: A method of forming nanowire devices. The method includes forming a stressor layer circumferentially surrounding a semiconductor nanowire. The method is performed such that, due to the stressor layer, the nanowire is subjected to at least one of radial and longitudinal strain to enhance carrier mobility in the nanowire. Radial and longitudinal strain components can be used separately or together and can each be made tensile or compressive, allowing formulation of desired strain characteristics for enhanced conductivity in the nanowire of a given device.

Abstract: The present invention relates to a highly reliable nonvolatile memory and a manufacturing method thereof. The nonvolatile memory comprises top electrodes, bottom electrodes and a resistive material layer disposed therebetween, wherein the top electrodes are positioned on top in the memory; the bottom electrodes are positioned on a substrate; metal oxide for forming the resistive material layer is doped with metal; and a metal oxygen storage layer is further disposed between the top electrodes and the resistive material layer. The manufacturing method adopts a method in which a doping method and a double-layer forming method are combined, so that the highly reliable and highly uniform resistive random access memory can be fabricated and accordingly the performance of the memory can be increased.

Abstract: A variable resistance memory device, and methods of manufacturing the same, include a plurality of first conductive structures extending in a first direction, a plurality of second conductive structures extending in a second direction crossing the first direction over the first conductive structures, the second conductive structures, and a plurality of memory cells that are formed at intersections at which the first conductive structures and the second conductive structures overlap each other, and each includes a selection element and a variable resistance element sequentially stacked. An upper surface of each of the first conductive structures has a width in the second direction less than a width of a bottom surface of each of the selection elements.

Abstract: A memory device is provided. The memory device includes bit lines that extend in a first direction on a substrate, word lines configured to vertically cross the bit lines, memory cells formed at intersections of the bit lines and the word lines, a first low permittivity layer configured to fill spaces between the bit lines and partially fill spaces between the memory cells formed on bottom surfaces of the word lines, a first dielectric layer stacked on an upper surface of the first low permittivity layer between the memory cells, a second dielectric layer configured to fill spaces between the memory cells formed on upper surfaces of the bit lines, and a second low permittivity layer stacked on an upper surface of the second dielectric layer and configured to fill spaces between the word lines. The first and second low permittivity layers have lower permittivity than the first and second dielectric layers.

Abstract: This disclosure provides a nonvolatile memory device and related methods of manufacture and operation. The device may include one or more resistive random access memory (ReRAM) approaches to provide a memory device with more predictable operation. In particular, the forming voltage required by particular designs may be reduced through the use of a barrier layer, a reverse polarity forming voltage pulse, a forming voltage pulse where electrons are injected from a lower work function electrode, or an anneal in a reducing environment. One or more of these techniques may be applied, depending on the desired application and results.

Abstract: According to one embodiment, a manufacturing method of a semiconductor memory device includes forming a stacked body in which word line material layers and insulating layers are alternately stacked on a base layer. The method includes forming first holes on the stacked body so as to be arranged in a first direction and in a second direction that intersects with the first direction. The method includes forming resistance-change films on inner walls of the first holes, forming bit lines inside the resistance-change films in the first holes, and dividing the stacked body in the first direction by forming second holes so that a portion in the stacked body adjacent to the resistance-change films in the second direction. The method includes forming inter-bit line insulating films in the second holes.

Abstract: A semiconductor structure includes a memory region. A memory structure is disposed on the memory region. The memory structure includes a first electrode, a resistance variable layer, protection spacers and a second electrode. The first electrode has a top surface and a first outer sidewall surface on the memory region. The resistance variable layer has a first portion and a second portion. The first portion is disposed over the top surface of the first electrode and the second portion extends upwardly from the first portion. The protection spacers are disposed over a portion of the top surface of the first electrode and surround the second portion of the resistance variable layer. The protection spacers are configurable to protect at least one conductive path in the resistance variable layer. The protection spacers have a second outer sidewall surface substantially aligned with the first outer sidewall surface of the first electrode.

Abstract: Providing for two-terminal memory cell structures and fabrication that can be achieved with a relatively low temperature process(es) is described herein. By way of example, disclosed two-terminal memory cells can be formed at least in part as a continuous deposition, potentially yielding improved efficiency in manufacturing. Furthermore, various embodiments can be compatible with some existing complementary metal oxide semiconductor fabrication processes, reducing or avoiding retooling overhead that might be associated with modifying existing fabrication processes in favor of other two-terminal memory cell fabrication techniques.

Abstract: A present method of fabricating a memory device includes the steps of providing a dielectric layer, providing an opening in the dielectric layer, providing a first conductive body in the opening, providing a switching body in the opening, the first conductive body and switching body filling the opening, and providing a second conductive body over the switching body. In an alternate embodiment, a second dielectric layer is provided over the first-mentioned dielectric layer, and the switching body is provided in an opening in the second dielectric layer.

Abstract: Disclosed is a method for manufacturing a chalcogenide switching device, which includes forming a first electrode on a substrate, forming a chalcogenide material composed of Gex and Se1-x formed on the first electrode, and forming a second electrode on the chalcogenide material, wherein the value x is greater than 0 and smaller than 1. A chalcogenide switching device manufactured by this method is also disclosed.

Abstract: Engineered substrates having epitaxial formation structures with enhanced shear strength and associated systems and methods are disclosed herein. In several embodiments, for example, an engineered substrate can be manufactured by forming a shear strength enhancement material at a front surface of a donor substrate and implanting ions a depth into the donor substrate through the shear strength enhancement material. The ion implantation can form a doped portion in the donor substrate that defines an epitaxial formation structure. The method can further include transferring the epitaxial formation structure from the donor substrate to a front surface of a handle substrate. The shear strength enhancement material can be positioned between the epitaxial formation structure and the front surface of the handle substrate and bridge defects in the front surface of the handle substrate.

Abstract: A system that incorporates teachings of the subject disclosure may include, for example, a device including a nanoelectrode having a gap, and a resistive change material located in the gap, wherein an application of a voltage potential across first and second terminals of the nanoelectrode causes the resistive change material to modify at least one non-volatile memory state of the resistive change material. Additional embodiments are disclosed.

Abstract: In a method of manufacturing a phase change memory device, an insulating interlayer having a through opening is formed on a substrate, at least one conformal phase change material layer pattern is formed along the sides of the opening, and a plug-like phase change material pattern having a composition different from that of each conformal phase change material layer pattern is formed on the at least one conformal phase change material layer pattern as occupying a remaining portion of the opening. Energy is applied to the phase change material layer patterns to form a mixed phase change material layer pattern including elements from the conformal and plug-like phase change material layer patterns.

Abstract: An ultra-high-density vertical cross-point array comprises a plurality of horizontal line layers having horizontal lines interleaved with a plurality of vertical lines arranged in rows and columns. The vertical lines are interleaved with the horizontal lines such that a row of vertical lines is positioned between each consecutive pair of horizontal lines in each horizontal line layer. Each vertical line comprises a center conductor surrounded by a single or multi-layered memory film. Accordingly, when interleaved with the horizontal lines, two-terminal memory cells are integrally formed between the center conductor of each vertical line and each crossing horizontal line. By configuring the vertical and horizontal lines so that a row of vertical lines is positioned between each consecutive pair of horizontal lines, a unit memory cell footprint of just 2F2 may be realized.

Abstract: Apparatus to store data and methods to read memory cells are disclosed. A disclosed example method involves, during a read cycle of a memory cell, applying a current across the memory cell to read a content of the memory cell. During a subsequent read cycle of the memory cell, a subsequent current is applied across the memory cell in the opposite direction to read the content of the memory cell.

Abstract: The present invention relates to a variable resistance memory device and a method for forming the same. A variable resistance memory device according to the present invention includes a first electrode; a second electrode spaced apart from the first electrode; a resistance variable layer and a metal-insulator transition layer provided between the first electrode and the second electrode; and a heat barrier layer provided (i) between the first electrode and the metal-insulator transition layer, (ii) between the metal-insulator transition layer and the resistance variable layer, or (iii) between the second electrode and the metal-insulator transition layer. The present invention prevents dissipation of heat generated in the metal-insulator transition layer using a thermal boundary resistance (TBR) phenomenon, and thus current and voltage to operate the variable resistance memory device can be reduced.

Abstract: An element according to an embodiment can transit between at least two states including a low-resistance state and a high-resistance state. The element comprises a first electrode, a second electrode, a first layer and a second layer. The first electrode includes metal elements. The first layer is located between the first electrode and the second electrode while contacting with the first electrode. The second layer is located between the first layer and the second electrode. At the low-resistance state, a density of the metal elements in the first layer is higher than that of the metal elements in the second layer. The density of the metal elements in the first layer at the low-resistance state is higher than that of the metal elements in the first layer at the high-resistance state. A relative permittivity of the second layer is higher than a relative permittivity of the first layer.

Abstract: Methods of forming memory cells comprising phase change and/or chalcogenide materials are disclosed. In one aspect, the method includes providing a lower line stack extending in a first direction, the lower line stack comprising a sacrificial line over a lower conductive line. The method further includes forming a chalcogenide line extending in the first direction by selectively removing the sacrificial material of the sacrificial line and replacing the sacrificial line with a chalcogenide material.

Abstract: A resistance memory includes a resistance memory cell having a resistance memory element and a two-terminal access device in series. The two-terminal access device affects the current-voltage characteristic of the resistance memory cell. The resistance memory additionally includes a circuit to apply across the resistance memory cell a set pulse having a set polarity to set the resistance memory cell to a low-resistance state that is retained after application of the set pulse, a reset pulse having a reset polarity, opposite to the set polarity, to reset the resistance memory cell to a high-resistance state that is retained after application of the reset pulse, and a read pulse of the reset polarity and smaller in magnitude than the reset pulse to determine the resistance state of the resistance memory cell without changing the resistance state of the resistance memory cell.

Abstract: A technique relates to an MRAM system. A conformal film covers trenches formed in an upper material. The upper material covers conductive islands in a substrate. The conformal film is selectively etched to leave sidewalls on the trenches. The sidewalls are etched into vertical columns self-aligned to and directly on top of the conductive islands below. A filling material is deposited and planarized to leave exposed tops of the vertical columns. An MTJ element is formed on top of the filling material and exposed tops of the vertical columns. The MTJ element is patterned into lines corresponding to the vertical columns, and each of the lines has a line MTJ element self-aligned to one of the vertical columns. Line MRAM devices are formed by patterning the MTJ element into the lines. Each of line MRAM devices respectively include the line MTJ element self-aligned to the one of the vertical columns.

Abstract: Some embodiments include integrated devices, such as memory cells. The devices may include chalcogenide material, an electrically conductive material over the chalcogenide material, and a thermal sink between the electrically conductive material and the chalcogenide material. The thermal sink may be of a composition that includes an element in common with the electrically conductive material and includes an element in common with the chalcogenide material. Some embodiments include a method of forming a memory cell. Chalcogenide material may be formed over heater material. Electrically conductive material may be formed over the chalcogenide material. A thermal sink may be formed between the electrically conductive material and the chalcogenide material. The thermal sink may be of a composition that includes an element in common with the electrically conductive material and includes an element in common with the chalcogenide material.

Abstract: A memory cell array having such a structure that can be realized with a simpler process and ideal for realizing a higher density is provided. Memory cells have a structure in which channel layers (88p and 89p) are formed on the side surfaces of each of a plurality of stacked structures which extends in the Y direction and is periodically formed in the X direction with a gate insulator film layer (9) interposed, and a resistance-change material layer (7) is formed so as to be electrically connected to two adjacent channel layers of the channel layers. Due to such a structure, it is not necessary to perform such a very difficult step that processes the resistance-change material and the silicons collectively and it is possible to provide the memory cell array with a simpler process.

Abstract: According to example embodiments, a nonvolatile memory cell includes a first electrode and a second electrode, a resistance change film between the first electrode and the second electrode, and a first barrier film contacting the second electrode. The resist change film contains oxygen ions and contacts the first electrode. The first barrier film is configured to reduce (and/or block) the outflow of the oxygen ions from the resistance change film.

Abstract: A variable resistance memory device includes a gate pattern and a dummy gate pattern provided at the same level on a substrate, a first contact pattern provided on the dummy gate pattern, and a variable resistance pattern provided between the dummy gate pattern and the first contact pattern. The gate pattern and the dummy gate pattern define conductive electrodes of functional and non-functional transistors, respectively. The first contact pattern and the dummy gate pattern define upper and lower electrodes on the variable resistance pattern, respectively. Related fabrication methods are also discussed.

Abstract: A radio frequency switch includes a first transmission line, a second transmission line, a first electrode electrically coupled to the first transmission line, a second electrode electrically coupled to the second transmission line, and a phase change material, the first transmission line coupled to a first area of the phase change material and the second transmission line coupled to a second area of the phase change material. When a direct current is sent from the first electrode to the second electrode through the phase change material, the phase change material changes state from a high resistance state to a low resistance state allowing transmission from the first transmission line to the second transmission line. The radio frequency switch is integrated on a substrate.

Abstract: According to one embodiment, a memory device includes a first conductive line extending in a first direction, second conductive lines each extending in a second direction intersect with the first direction, a third conductive line extending in a third direction intersect with the first and second directions, an insulating layer disposed between the second conductive lines and the third conductive line, resistance change elements each disposed on one of first and second surfaces of each of the second conductive lines in the third direction, and each connected to the third conductive line, a semiconductor layer connected between the first conductive line and one end of the third conductive line, and a select FET having a select gate electrode, and using the semiconductor layer as a channel.

Abstract: A memory device includes a first metal layer and a first metal oxide layer coupled to the first metal layer. The memory device includes a second metal oxide layer coupled to the first metal oxide layer and a second metal layer coupled to the second metal oxide layer. The formation of the first metal oxide layer has a Gibbs free energy that is lower than the Gibbs free energy for the formation of the second metal oxide layer.

Abstract: A memory structure and a method for manufacturing the same are provided. The memory structure comprises a substrate, stacks, memory layers, a conductive material and conductive lines. The stacks are positioned on the substrate. The stacks are separated from each other by trenches. Each of the stacks comprises alternately stacked conductive stripes and insulating stripes. The memory layers conformally cover the stacks respectively. The conductive material is positioned in the trenches and on the stacks. The conductive material in the trenches forms one or more holes in each of the trenches. The conductive lines are positioned on the conductive material. Each of the conductive lines comprises a first portion and a second portion connected to each other, the first portion extends along a direction perpendicular to an extending direction of the stacks, and the second portion extends along the extending direction of the stacks.

Abstract: The present invention provides a memory structure including a resistance-changing storage element, which enables a reset operation with a reset gate and in which cross-sectional areas of a resistance-changing film and a lower electrode in a current-flowing direction can be decreased.

Abstract: The present invention provides a phase-change storage unit containing a TiSiN material layer and a method for preparing the same. The phase-change storage unit includes a phase-change material layer and a lower electrode located there below, the phase-change material layer and the lower electrode are connected by a TiSiN material layer, the lower electrode includes a bottom and a sheet side connected to the bottom, the sheet side is perpendicular to the bottom to form a blade structure, and the top of the sheet side contacts the TiSiN material layer. The present invention adopts annealing to increase the grain size of the electrode so as to reduce the overall resistance of the device and form a TiSiN material layer on the top of the lower electrode so as to reduce the effective operation region. The phase-change storage unit of the present invention is applied to a phase-change memory to achieve the advantages such as low power consumption, high density and high data retention performance.

Abstract: A read-only memory (ROM) cell array and a cell structure thereof is disclosed. The ROM cell array is coupled to a plurality rows of bit-lines and a plurality columns of word-lines and comprises: a plurality of sub-cell-arrays arranged along the column direction, each sub-cell-array comprising a plurality of unit cell structures. Each unit cell structure comprises: an cell base region defining a cell boundary, comprising an blanket OD layer having a wide-block profile arranged on a substrate and defining a continuous common source node, a drain pad disposed above the OD layer, arranged in selectively connection with a bit line, a vertical channel structure bridging between the drain pad and the OD layer, and a gate structure disposed vertically between the drain pad and the OD layer and arranged in connection with a word-line. The sub-cell-array boundary is defined entirely within the coverage of the OD layer.

Abstract: According to one embodiment, a storage device includes first electrodes, second electrodes, a resistance change layer provided between the first electrodes and the second electrodes, and ion metal particles that are formed in an island form between the first electrodes and the resistance change layer and that contain a metal movable inside the resistance change layer. The first electrodes and the second electrodes are formed of a material which is more unlikely to be ionized as compared to the metal, and the first electrodes are in contact with the resistance change layer in an area around the ion metal particles.