Abstract: A reversible resistance-switching memory cell has multiple narrow, spaced apart bottom electrode structures. The raised structures can be formed by coating a bottom electrode layer with nano-particles and etching the bottom electrode layer. The raised structures can be independent or joined to one another at a bottom of the bottom electrode layer. A resistance-switching material is provided between and above the bottom electrode structure, followed by a top electrode layer. Or, insulation is provided between and above the bottom electrode structures, and the resistance-switching material and top electrode layer are above the insulation. Less than one-third of a cross-sectional area of each resistance-switching memory cell is consumed by the one or more raised structures. 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 three-dimensional (3D) non-volatile memory array having a silicide bit line and method of fabricating is disclosed. The fabrication technique may comprise forming a metal silicide for at least a portion of the bit line. The device has reversible resistivity material between the word lines and the bit lines. The reversible resistivity material may be a metal oxide. The metal that is used to form the silicide may serve as an oxygen scavenger to draw oxygen away from the silicon, thus preventing formation of silicon oxide between the reversible resistivity material and the bit line. The metal silicide may also help prevent formation of a depletion layer in silicon in the bit line.

Abstract: A joint short-time and long-time storage device, including a first electrode layer, a functional material layer connected to the first electrode layer, and a second electrode layer connected to the functional material layer. The first electrode layer is made of inert conductive metal, the second electrode layer is made of active conductive metal, and the functional material layer is made of chalcogenide.

Abstract: A resistive memory apparatus and a reading method thereof are provided. In this method, two reading pulses are applied to a resistive memory cell, such that a first reading resistance and a second reading resistance of the resistive memory cell at different temperatures are sequentially obtained. Next, a resistive state of the second reading resistance is determined according to the reading resistances and the temperatures corresponding to the reading resistances. Thereafter, a logic level of storage data of the resistive memory cell is determined according to the resistive state of the second reading resistance.

Abstract: A 3D NAND flash memory includes even and odd stacks of conductive strips. Some of the conductive strips in the stacks are configured as word lines. Data storage structures are disposed on the sidewalls of the even and odd stacks. Active pillars include even and odd semiconductor films on the data storage structures connected at the bottom ends so that the semiconductor films can be thin films having a U-shaped current path. An even pad connected to the even semiconductor film and an odd pad connected to the odd semiconductor film are disposed over the even and odd stacks respectively. A segment of a reference line is connected to the even pad, and an inter-level connector is connected to the odd pad. A segment of a bit line comprises an extension contacting the inter-level connector.

Abstract: Various embodiments herein relate to methods and apparatus for depositing a bilayer barrier layer on a substrate. The bilayer barrier layer may include a first sub-layer designed to protect underlying halide-sensitive layers from damaging halide-containing chemistry, as well as a second sub-layer designed to protect underlying materials from damage due to oxidation. In a number of embodiments the first sub-layer is layer having a high carbon content, and the second layer is silicon nitride. The silicon nitride second sub-layer may be deposited with halide-containing chemistry that would otherwise damage halide-sensitive materials, if not for the presence of the first sub-layer. The resulting bilayer barrier layer provides high quality protection for underlying materials.

Abstract: A memory system according to the embodiment comprises a cell array of plural cells having three or more settable physical quantity levels and operative to store a code composed of symbols expressed by elements in a finite field Zp (p is a prime), wherein a set of two cells is defined as a pair cell and a combination of physical quantity levels of the two cells contained in the pair cell is defined as a pair cell level, wherein the pair cell uses a pair cell level of plural pair cell levels, which maximizes or minimizes a physical quantity level of one cell contained in the pair cell, to assign elements in the Zp to the pair cell levels, thereby storing symbols of the code.

Abstract: Memory cells having heaters with angled sidewalls and methods of forming the same are described herein. As an example, a method of forming an array of resistive memory cells can include forming a first resistive memory cell having a first heater element angled with respect to a vertical plane, forming a second resistive memory cell adjacent to the first resistive memory cell and having a second heater element angled with respect to the vertical plane and toward the first heater, and forming a third resistive memory cell adjacent to the first resistive memory cell and having a third heater element angled with respect to the vertical plane and away from the first heater element.

Abstract: A semiconductor memory device according to an embodiment comprises: a plurality of first lines extending in a first direction perpendicular to a substrate surface and arranged with a certain pitch in a second direction parallel to the substrate surface; a plurality of second lines extending in the second direction and arranged with a certain pitch in the first direction; a memory cell provided at an intersection of the first line and the second line and including a variable resistance element; a third line provided extending in the second direction between the plurality of second lines; and a control circuit capable of executing a first operation that changes a resistance value of the variable resistance element by applying a voltage to the memory cell via the first line and the second line, and a second operation that supplies heat to the memory cell using the third line.

Abstract: Resistive memory cell structures and methods are described herein. One or more memory cell structures comprise a first resistive memory cell comprising a first resistance variable material and a second resistive memory cell comprising a second resistance variable material that is different than the first resistance variable material.

Abstract: Some embodiments include a memory cell having a data storage region between a pair of conductive structures. The data storage region is configured to support a transitory structure which alters resistance through the memory cell. The data storage region includes two or more portions, with one of the portions supporting a higher resistance segment of the transitory structure than another of the portions. Some embodiments include a method of forming a memory cell. First oxide and second oxide regions are formed between a pair of conductive structures. The oxide regions are configured to support a transitory structure which alters resistance through the memory cell. The oxide regions are different from one another so that one of the oxide regions supports a higher resistance segment of the transitory structure than the other.

Abstract: Combinatorial workflow is provided for evaluating materials and processes for current selector devices in a cross point memory array. Blanket layers, metal-insulator-metal devices, and compete memory structures are combinatorially fabricated on multiple regions of a substrate, with each region having a different material and process condition for the current selector devices. The current selector devices are then characterized, and the data are compared to obtain the optimum materials and processes.

Abstract: A nonvolatile semiconductor memory element includes: a variable resistance element including a first electrode, a variable resistance layer, and a second electrode, and having a resistance value which changes according to a polarity of an electric pulse applied between the first electrode and the second electrode; and a current steering element which is electrically connected to the variable resistance element, allows a current to flow bidirectionally, and has a nonlinear current-voltage characteristic. The current steering element (i) has a structure in which a first current steering element electrode, a first current steering layer, and a second current steering element electrode are stacked in this order, and (ii) includes a second current steering layer which covers side surfaces of the first current steering element electrode, the first current steering layer, and the second current steering element electrode.

Abstract: Three dimension memory arrays and methods of forming the same are provided. An example three dimension memory array can include a stack comprising a plurality of first conductive lines 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, such that the at least one conductive extension intersects a portion of at least one of 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.

Abstract: A storage device includes: a first electrode; a storage layer including an ion source layer; and a second electrode. The first electrode, the storage layer, and the second electrode are provided in this order. The ion source layer contains a movable element, and has a volume resistivity of about 150 m?·cm to about 12000 m?·cm both inclusive.

Abstract: Embodiments of a resistive random access memory (RRAM) cell structure are provided. The RRAM cell structure includes a first electrode over a substrate. The RRAM cell structure also includes a resistance variable layer over the first electrode. The resistance variable layer has a first portion in a V-shape. The RRAM cell structure further includes a second electrode over the resistance variable layer.

Abstract: A three-dimensional semiconductor device includes first and second selection lines stacked one on the other. An upper line horizontally crosses over the first and second selection lines. First and second vertical patterns vertically cross the first and second selection lines. The first and second vertical patterns are connected in common to the upper line. Each of the first and second vertical patterns constitutes first and second selection transistors that are connected in series to each other. The first selection transistors of the first and second vertical patterns are controlled by the first and second selection lines, respectively.

Abstract: A chalcogenide-based programmable conductor memory device and method of forming the device, wherein a nanoparticle is provided between an electrode and a chalcogenide glass region. The method of forming the nanoparticle utilizes a template over the electrode or random deposition of the nanoparticle.

Abstract: A method for fabricating a semiconductor device includes forming a first conductive pattern and a first pad over a substrate; forming a first and a second resistance variable elements over the first conductive pattern and the first pad, respectively; performing impurity doping into the second resistance variable element to produce a conductive contact; and forming a second conductive pattern over the first resistance variable element.

Abstract: An electronic device includes a semiconductor memory circuit. The semiconductor memory circuit includes a plurality of first conductive lines which includes an anti-oxidation layer on both sides of each first conductive line, an inter-layer dielectric layer suitable for gap-filling a space between the first conductive lines, a material layer formed over the first conductive lines and the inter-layer dielectric layer and including oxygen vacancies, and a plurality of second conductive lines formed over the material layer to intersect with the first conductive lines. A first portion of the material layer where the first conductive lines and the second conductive lines overlap each other has a lower oxygen content than a second portion of the material layer where the inter-layer dielectric layer and the second conductive lines overlap each other.

Abstract: According to example embodiments of inventive concepts, a semiconductor memory devices includes: a plurality of memory blocks that each include a plurality of stack structures, global bit lines connected in common to the plurality of memory blocks, block selection lines configured to control electrical connect between the global bit lines and one of the plurality of memory blocks, and vertical selection lines configured to control electrical connected between the global bit lines and one of the plurality of stack structures. Each of the plurality of stack structures includes a plurality of local bit lines, first vertical word lines and second vertical word lines crossing first sidewalls and second sidewalls respectfully of the plurality of stack structures, first variable resistive elements between the plurality of stack structures and the first vertical word lines, and second variable resistive elements between the plurality of stack structures and the second vertical word lines.

Abstract: A semiconductor memory device includes pillars extending upright on a substrate in a direction perpendicular to the substrate, a stack disposed on the substrate and constituted by a first interlayer insulating layer, a first conductive layer, a second interlayer insulating layer, and a second conductive layer, a variable resistance layer interposed between the pillars and the first conductive layer, and an insulating layer interposed between the first pillars and the second conductive layer.

Abstract: A semiconductor memory device according to an embodiment comprises a memory cell array configured from a plurality of row lines and column lines that intersect one another, and from a plurality of memory cells disposed at each of intersections of the row lines and column lines and each including a variable resistance element. Where a number of the row lines is assumed to be N, a number of the column lines is assumed to be M, and a ratio of a cell current flowing in the one of the memory cells when a voltage that is half of the select voltage is applied to the one of the memory cells to a cell current flowing in the one of the memory cells when the select voltage is applied to the one of the memory cells is assumed to be k, a relationship M2<2×N×k is satisfied.

Abstract: Provided is a resistive random access memory including a first electrode layer, a second electrode layer, and a variable resistance layer disposed between the first electrode layer and the second electrode layer, wherein the second electrode layer includes a first sublayer, a second sublayer, and a conductive metal oxynitride layer disposed between the first sublayer and the second sublayer.

Abstract: The disclosed technology provides an electronic device and a fabrication method thereof. An electronic device according to an implementation of the disclosed technology may include: a first interlayer insulating layer formed over a substrate; first and second contact plugs passing through the first interlayer insulating layer to contact the substrate and alternately arranged to cross each other; a variable resistance element formed over the first interlayer insulating layer and coupled to the first contact plug; a second interlayer insulating layer formed over an entire structure including the first interlayer insulating layer; a third contact plug passing through the second interlayer insulating layer so as to be coupled to the variable resistance element, and a fourth contact plug passing through the second interlayer insulating layer so as to be contacted to the second contact plug; and conductive lines coupled to the third contact plug and the fourth contact plug, respectively.

Abstract: Some embodiments include selectively conducting devices having a first electrode, a second electrode, and dielectric material between the first and second electrodes. The dielectric material may be configured to conduct current from the first electrode to the second electrode when a first voltage is applied across the first electrode and the second electrode. Furthermore, the dielectric material may be configured to inhibit current from flowing from the second electrode to the first electrode when a second voltage having a polarity opposite that of a polarity of the first voltage is applied across the first electrode and the second electrode. The diode material may comprise a plurality of layers of different dielectric materials arranged in order of increasing barrier height. Quantum wells may form at junctions of layers of the plurality responsive to the first voltage. Some embodiments include diode forming methods.

Abstract: A method including: forming a stack of resistive layers; prior to or subsequent to forming the stack of resistive layers, forming a conductive layer; applying a mask layer on the stack of resistive layers or the conductive layer; forming a first spacer on the mask layer; and etching away a first portion of the mask layer using the first spacer as a first mask to provide a remainder. The method further includes: forming a second spacer on the stack of the resistive layers or the conductive layer and the remainder of the mask layer; etching away a second portion of the remainder of the mask layer to form an island; and using the island as a second mask, etching the stack of the resistive layers to form a resistive element of a memory, and etching the conductive layer to form a conductive element of the memory.

Abstract: A memory device includes a first electrode, a second electrode, a third electrode, a first variable resistance layer between the first electrode and the third electrode, and a second variable resistance layer between the second electrode and the third electrode. The first, second, and third electrodes, and the first and second variable resistance layers are formed of materials that cause the first variable resistance layer to transition from a high resistance state to a low resistance state when a voltage is applied across the first and second electrodes and maintain the high resistance state when the voltage is cut off, and cause the second variable resistance layer to transition from a high resistance state to a low resistance state when the voltage is applied across the first and second electrodes and transition from the high resistance state to the low resistance state when the voltage is cut off.

Abstract: A method for manufacturing a resistive memory element includes providing a storage layer comprising a resistance changeable material, said resistance changeable material comprising carbon; providing contact layers for contacting the storage layer, wherein the storage layer is disposed between a bottom contact layer and a top contact layer; and doping the resistance changeable material with a dopant material.

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: According to one embodiment, a nonvolatile semiconductor memory device includes a fin-type stacked layer structure having memory cells, and a beam connected to an end portion of the structure. Each of the structure and the beam includes semiconductor layers stacked in a perpendicular direction. The beam includes a contact portion provided at one end of the beam, and a low resistance portion provided between the contact portion and the end portion of the structure.

Abstract: An embodiment of the present invention sets forth an embedded resistive memory cell that includes a first stack of deposited layers, a second stack of deposited layers, a first electrode disposed under a first portion of the first stack, and a second electrode disposed under a second portion of the first stack and extending from under the second portion of the first stack to under the second stack. The second electrode is disposed proximate to the first electrode within the embedded resistive memory cell. The first stack of deposited layers includes a dielectric layer, a high-k dielectric layer disposed above the dielectric layer, and a metal layer disposed above the high-k dielectric layer. The second stack of deposited layers includes a high-k dielectric layer formed simultaneously with the high-k dielectric layer included in the first stack, and a metal layer disposed above the high-k dielectric layer.

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: Technology capable of improving performance of a phase-change memory is provided. A recording/reproducing film contains Sn (tin), Sb (antimony), and Te (tellurium) and also contains an element X having a bonding strength with Te stronger than a bonding strength between Sn and Te and a bonding strength between Sb and Te. Here, the recording/reproducing film has a (SnXSb)Te alloy phase, and this (SnXSb)Te alloy phase includes a self-assembled superlattice structure.

Abstract: A semiconductor memory storage array device comprises a first electrode layer, an oxide layer, a second electrode layer, a memory material layer and a first insulator layer. The oxide layer is disposed on the first electrode layer. The second electrode layer is disposed on the oxide layer. The memory material layer is disposed on the second electrode layer. The first insulator layer is disposed adjacent to two sidewalls of the first electrode layer, the oxide layer, the second electrode layer and the memory material layer, so to define a gap either between the first electrode layer and the oxide layer or between the second electrode layer and the oxide layer.

Abstract: An electrically actuated device comprises an active region disposed between a first electrode and a second electrode, a substantially nonrandom distribution of dopant initiators at an interface between the active region and the first electrode, and a substantially nonrandom distribution of dopants in a portion of the active region adjacent to the interface.

Abstract: According to one embodiment, an information recording device includes first and second electrodes, a variable resistance layer between the first and second electrodes, and a control circuit which controls the variable resistance layer to n (n is a natural number except 1) kinds of resistance. The variable resistance layer comprises a material filled between the first and second electrodes, and particles arranged in a first direction from the first electrode to the second electrode in the material, and each of the particles has a resistance lower than that of the material. A resistance of the variable resistance layer is decided by a short between the first electrode and at least one of the particles.

Abstract: A semiconductor device includes a first conductive layer extending in a first direction, a second conductive layer extending in a second direction and disposed over the first conductive layer, the first and second directions being substantially perpendicular to each other, and a variable resistance layer disposed over the first conductive layer, the variable resistance layer extending in the second direction. An upper portion of the variable resistance layer is disposed between lower portions of two neighboring second conductive layers including the second conductive layer.

Abstract: An electronic device includes a memory. The memory includes a first cell array including a plurality of flash memory cells, a first peripheral circuit suitable for controlling the first cell array, a second cell array including a plurality of variable resistance memory cells, and a second peripheral circuit suitable for controlling the second cell array. The first cell array, the first peripheral circuit, and the second peripheral circuit are formed at a first level over a surface of a semiconductor substrate, and the second cell array is disposed at a second level over the surface of a semiconductor substrate, the second level being higher than the first level. A portion of the second cell array overlaps in a plan view the second peripheral circuit and/or the first cell array.

Abstract: A self-aligning stacked memory cell array structure and method for fabricating such structure. The memory cell array includes a stack of memory cells disposed adjacent to opposing sides of a conductive line that is formed within a trench. The memory cells are stacked such that the memory element surface of each memory cell forms a portion of the sidewall of the conductive line. The conductive line is formed within the trench such that electrical contact is made across the entire memory element surface of each memory cell. Such structure and method for making such structure is a self-aligning process that does not require the use of any additional masks.

Abstract: A variable resistance memory device includes a plurality of cell blocks each of which includes a plurality of first lines extending in parallel to each other along a first direction, a plurality of second lines extending in parallel to each other along a second direction crossing the first direction, and a plurality of memory cells including variable resistance layers arranged at intersections of the plurality of first lines and the plurality of second lines and a plurality of selection units coupled to the plurality of first lines and coupling two neighboring cell blocks.

Abstract: A memristor structure has two electrodes sandwiching an insulating region, and includes a nanoparticle providing a conducting path between the two electrodes, wherein either the insulating region comprises an inorganic material and nanoparticle comprises a solid nanoparticle or a core/shell nanoparticle or the insulating region comprises an inorganic or organic material and the nanoparticle comprises a core/shell nanoparticle.

Abstract: The present invention relates to integrating a resistive memory device on top of an IC substrate monolithically using IC-foundry compatible processes.

Abstract: A memory device includes a first plurality of memory cells arranged in a first crossbar array, a first thickness of dielectric material overlying the first plurality of memory cells, and a second plurality of memory cells arranged in a second crossbar array overlying the first thickness of dielectric material. The memory device further includes a second thickness of dielectric material overlying the second plurality of memory cells. In a specific embodiment, the memory device further includes a Nth thickness of dielectric material overlying an Nth plurality of memory cells, where N is an integer ranging from 3 to 8.

Abstract: Providing for one time programmable, multi-level cell two-terminal memory is described herein. In some embodiments, the one time programmable, multi-level cell memory can have a 1 diode 1 resistor configuration, per memory cell. A memory cell according to one or more disclosed embodiments can be programmed to one of a set of multiple logical bits, and can be configured to mitigate or avoid erasure. Accordingly, the memory cell can be employed as a single program, non-erasable memory. Expressed differently, the memory cell can be referred to as a write once read many (WORM) category of memory.

Abstract: A nano-ionic memory device is provided. The memory device includes a substrate, a chemically inactive lower electrode provided on the substrate, a solid electrolyte layer provided on the lower electrode and including a silver (Ag)-doped telluride (Te)-based nano-material, and an oxidizable upper electrode provided on the electrolyte layer.

Abstract: A memory cell includes a first resistive switching device having a first terminal and a second terminal, a switching device having a first terminal and a second terminal, and an access device having a first access terminal and a second access terminal. The first access terminal is coupled to the first terminal of the first resistive switching device and the first terminal of the switching device.

Abstract: A device, including: a first layer including first transistors and a second layer including second transistors, where at least one of the first transistors is self-aligned to one of the second transistors, where the second transistors are horizontally oriented transistors, and where the second layer includes a plurality of resistive-random-access memory (RRAM) cells, the memory cells including the second transistors.

Abstract: A nanoscale switching device is provided. The device comprises: a first electrode of a nanoscale width; a second electrode of a nanoscale width; an active region disposed between the first and second electrodes, the active region having a non-conducting portion comprising an electronically semiconducting or nominally insulating and a weak ionic conductor switching material capable of carrying a species of dopants and transporting the dopants under an electric field and a source portion that acts as a source or sink for the dopants; and an oxide layer either formed on the first electrode, between the first electrode and the active region or formed on the second electrode, between the second electrode and the active region. A crossbar array comprising a plurality of the nanoscale switching devices is also provided. A process for making at least one nanoscale switching device is further provided.

Abstract: Embodiments of the present invention provide an array substrate, a manufacturing method thereof and a display device. The manufacturing method of an array substrate, comprising: forming a gate electrode on a base substrate by a first patterning process, and then depositing a gate insulating layer on the base substrate on which the gate electrode is formed; forming source and drain electrodes on the base substrate obtained after the above step, by a second patterning process; forming an active layer formed of a graphene layer, and a protective layer disposed on the active layer, on the base substrate obtained after the above steps, by a third patterning process; and forming a planarizing layer on the base substrate, obtained after the above steps, by a fourth patterning process, in which the planarizing layer is provided with a through hole through which the source or drain electrode is exposed.