Abstract: The invention is related to methods and apparatus for providing a resistance variable memory element with improved data retention and switching characteristics. According to an embodiment of the invention a resistance variable memory element is provided having at least one silver-selenide layer in between glass layers, wherein at least one of the glass layers is a chalcogenide glass, preferably having a GexSe100-x composition.

Abstract: According to one embodiment, a nonvolatile memory device includes a memory cell connected to a first interconnect and a second interconnect. The memory cell includes a plurality of layers. The plurality of layers includes a carbon-containing memory layer sandwiched between a first electrode film and a second electrode film and a carbon-containing barrier layer provided at least one of between the first electrode film and the memory layer and between the second electrode film and the memory layer. The barrier layer has lower electrical resistivity than the memory layer.

Abstract: An electrically actuated device includes a first electrode and a second electrode crossing the first electrode at a non-zero angle, thereby forming a junction therebetween. A material is established on the first electrode and at the junction. At least a portion of the material is a matrix region. A current conduction channel extends substantially vertically between the first and second electrodes, and is defined in at least a portion of the material positioned at the junction. The current conduction channel has a controlled profile of dopants therein.

Abstract: A method of making a device includes forming a first photoresist layer over a sacrificial layer, patterning the first photoresist layer to form first photoresist features, rendering the first photoresist features insoluble to a solvent, forming a second photoresist layer over the first photoresist features, patterning the second photoresist layer to form second photoresist features, forming a spacer layer over the first and second photoresist features, etching the spacer layer to form spacer features and to expose the first and second photoresist features, forming third photoresist features between the spacer features, removing the spacer features, and patterning the sacrificial layer using the first, second and third photoresist features as a mask to form sacrificial features.

Abstract: A memory storage device includes: a lower electrode formed to be separated for each of memory cells; a memory storage layer formed on the lower electrode and capable of recording information according to a change in resistance; and an upper electrode formed on the memory storage layer, wherein the memory storage device includes a first layer formed of metal or metal silicide and a second layer formed on the first layer and formed of a metal nitride, the lower electrode is formed by lamination of the first layer and the second layer and formed such that only the first layer is in contact with a lower layer and only the second layer is in contact with the memory storage layer, which is an upper layer, the memory storage layer is formed in common to plural memory cells, and the upper electrode is formed in common to the plural memory cells.

Abstract: Annular, linear, and point contact structures are described which exhibit a greatly reduced susceptibility to process deviations caused by lithographic and deposition variations than does a conventional circular contact plug. In one embodiment, a standard conductive material such as carbon or titanium nitride is used to form the contact. In an alternative embodiment, a memory material itself is used to form the contact. These contact structures may be made by various processes, including chemical mechanical planarization and facet etching.

Abstract: A semiconductor device is comprised of a semiconductor substrate, conductive layers stacked above the semiconductor substrate, which is comprised of a conductive polysilicon, and a metal layer provided above the conductive layers. Both ends of the conductive layers have stairsteps respectively. The conductive layers are connected in series by a metal layer which is provided on the stairsteps. The conductive layers connected in series comprise a resistance element.

Abstract: A phase change memory cell, e.g. a line-cell (2), and fabrication thereof, the cell comprising: two electrodes (6, 8); phase change memory material (10) and a dielectric barrier (12). The dielectric barrier (12) is arranged to provide electron tunnelling, e.g. Fowler-Nordheim tunnelling, to the phase change memory material (10). A contact (15) made of phase change memory material may also be provided. The dielectric barrier (12) is substantially uniform e.g. of substantially uniform thickness, e.g. ?5 nm.

Abstract: A method of fabricating a programmable memory microelectronic device includes depositing onto a first electrode an intermediate layer of a material having a chalcogenide; depositing an ionizable metallic layer on the intermediate layer; irradiating with ultraviolet radiation the ionizable metallic layer so that metallic ions from the ionizable metallic layer diffuse into the intermediate layer to form a chalcogenide material containing metallic ions, and depositing a second electrode on the layer of chalcogenide material containing metallic ions obtained in the prior step. The second and third steps are repeated at least n times, where n is an integer greater than or equal to 1. The ionizable metallic layer deposited during the second step has a sufficiently small thickness that the metallic ions may be diffused totally during the irradiation (third) step.

Abstract: A semiconductor device and a method of forming the same are provided. The method includes preparing a semiconductor substrate. Insulating layers may be sequentially formed on the semiconductor substrate. Active elements may be formed between the insulating layers. A common node may be formed in the insulating layers to be electrically connected to the active elements. The common node and the active elements may be 2-dimensionally and repeatedly arranged on the semiconductor substrate.

Abstract: Embodiments relate to a semiconductor device, and more particularly, to a semiconductor device and a manufacturing method thereof that can reduce RC delay within the semiconductor device. Embodiments provide a semiconductor device including: a first interlayer dielectric layer formed over the a semiconductor substrate, a first metal wire and a second metal wire formed over the first interlayer dielectric layer, a second interlayer dielectric layer formed over the first and second metal wires, and a phase change material layer formed between the first and second metal wires.

Abstract: An embedded memory required for a high performance, multifunction SOC, and a method of fabricating the same are provided. The memory includes a bipolar transistor, a phase-change memory device and a MOS transistor, adjacent and electrically connected, on a substrate. The bipolar transistor includes a base composed of SiGe disposed on a collector. The phase-change memory device has a phase-change material layer which is changed from an amorphous state to a crystalline state by a current, and a heating layer composed of SiGe that contacts the lower surface of the phase-change material layer.

Abstract: A semiconductor memory device includes a word line interconnect layer having a plurality of word lines extending in a word line direction and a bit line interconnect layer having a plurality of bit lines extending in a bit line direction alternately stacked on a silicon substrate. A variable resistance film is disposed between the word line and the bit line. A first pin diode extending in the word line direction is provided between the word line and the variable resistance film, and a second pin diode extending in the bit line direction is provided between the bit line and the variable resistance film. A region of an upper surface of the pin diode other than an immediately underlying region of the variable resistance film is located lower than the immediately underlying region.

Abstract: Phase change memory cell structures and methods are described herein. A number of methods of forming a phase change memory cell structure include forming a dielectric stack structure on a first electrode, wherein forming the dielectric stack structure includes creating a second region between a first region and a third region of the dielectric stack structure, the second region having a thermal conductivity different than a thermal conductivity of the first region and different than a thermal conductivity of the third region of the dielectric stack. One or more embodiments include forming a via through the first, second, and third regions of the dielectric stack structure, depositing a phase change material in the via, and forming a second electrode on the phase change material.

Abstract: A small critical dimension element, such as a heater for an ovonic unified memory, may be formed within a pore by using successive sidewall spacers. The use of at least two successive spacers enables the limitations imposed by lithography and the limitations imposed by bread loafing be overcome to provide reduced critical dimension elements.

Abstract: In a nonvolatile semiconductor memory device, there is provided a technique which promotes microfabrication by reducing a thickness of the device as suppressing an OFF current of a polysilicon diode which is a selective element. A polysilicon layer to which an impurity is doped at low concentration and which becomes an electric-field relaxation layer of the polysilicon diode which is a selective element of a resistance variable memory is formed so as to be divided into two or more layers such as polysilicon layers. In this manner, it is suppressed to form the crystal grain boundaries thoroughly penetrating between an n-type polysilicon layer and a p-type polysilicon layer in the electric-field relaxation layer, and therefore, it is prevented to generate a leakage current flowing through the crystal grain boundaries in application of a reverse-bias voltage without increasing a height of the polysilicon diode.

Abstract: A nanoscale switching device comprises at least two electrodes, each of a nanoscale width; and an active region disposed between and in electrical contact with the electrodes, the active region containing a switching material capable of carrying a species of dopants and transporting the dopants under an electrical field, wherein at least one of the electrodes comprises an amorphous conductive material.

Abstract: An exemplary hollow stylus-shaped structure is disclosed, including a hollow column spacer formed over a base layer and a hollow cone spacer stacked over the hollow column spacer, wherein the hollow cone spacer, the hollow column spacer, and the base layer form a space, and sidewalls of the hollow cone spacer and the hollow column spacer are made of silicon-containing organic or inorganic materials.

Abstract: A memory device comprising a first electrode having a top side, a second electrode having a top side and an insulating member between the first electrode and the second electrode. The insulating member has a thickness between the first and second electrodes near the top side of the first electrode and the top side of the second electrode extends outwardly from the top sides of the first and second electrodes defining a wall of insulating material having top side. A bridge of memory material crosses the insulating member over the top of the wall, and defines an inter-electrode path between the first and second electrodes across the insulating member. An array of such memory cells is provided. The bridge comprises an active layer of memory material on the top side of the wall, having at least two solid phases and a layer of thermal insulating material overlying the memory material having thermal conductivity less than a thermal conductivity of the first and second electrodes.

Abstract: An apparatus includes a mechanical switch. The mechanical switch includes a bilayer with first and second stable curved states. A transformation of the bilayer from the first state to the second state closes the switch.

Abstract: The electrode of a phase change memory may be formed with a mixture of metal and a non-metal, the electrode having less nitrogen atoms than metal atoms. Thus, in some embodiments, at least a portion of the electrode has less nitrogen than would be the case in a metal nitride. The mixture can include metal and nitrogen or metal and silicon, as two examples. Such material may have good adherence to chalcogenide with lower reactivity than may be the case with metal nitrides.

Abstract: A memory device comprising a first electrode, a second electrode, metal-chalcogenide material between the first and second electrodes and chalcogenide glass between the first and second electrodes. The chalcogenide glass comprises a material with the chemical formula AxB100-x, wherein A is a non-chalcogenide component and B is a chalcogenide component, and A has a bonding affinity for B relative to homopolar bonds of A. The memory device further comprises a conducting channel in the chalcogenide glass comprising bonds formed between A and a component of the metal chalcogenide material.

Abstract: A fin-type programmable memory cell includes a bottom electrode electrically coupled to an access device, a top electrode, and an L-shaped memory material element electrically coupled to the bottom and top electrodes. A memory array includes an array of such memory cells, electrically coupled to an array of access devices.

Abstract: A micro-switching element provided with a first electrode 4 containing an ionic conductor and a second electrode 5 composed of an electric conductor, wherein the first electrode 4 and the second electrode 5 are physically and electrically connected to each other through deposition of a metal ion from the ionic conductor, and wherein a photoresponsive film 9 that receives light to generate a carrier is disposed between the first electrode 4 and the second electrode 5 to fill up the space between the electrodes. Accordingly, a micro-switching element is provided of which the characteristic fluctuation is small and which hardly produces a problem of operation failure.

Abstract: A semiconductor device comprises a semiconductor substrate; a multilevel wiring layer structure on the semiconductor substrate; and a variable resistance element in the multilevel wiring layer structure, wherein the variable resistance element comprises a variable resistance element film whose resistance changes between a top electrode and a bottom electrode, wherein the multilevel wiring layer structure comprises at least a wiring electrically connected to the bottom electrode and a plug electrically connected to the top electrode, and wherein the wiring also serves as the bottom electrode.

Abstract: Provided are a resistive memory device and a method of fabricating the same. The resistive memory device comprises an electron channel layer formed by means of a swelling process and an annealing process. Thus, conductive nanoparticles are uniformly dispersed in the electron channel layer to improve reliability of the resistive memory device. According to the method, an electron channel layer is formed by means of a printing process, a swelling process, and an annealing process. Thus, fabrication time is reduced.

Abstract: In a phase-change semiconductor device and methods of manufacturing the same, an example method may include forming a metal layer pattern on a substrate, the metal layer pattern including an opening that exposes a portion of the substrate, forming an etch stop layer on the metal layer pattern, a sidewall of the opening and the exposed portion of the substrate, the etch stop layer formed with a thickness less than an upper thickness threshold, and reducing at least a portion of the etch stop layer, the reduced portion of the etch stop layer forming an electrical connection with the substrate.

Abstract: A memory cell is provided, the memory cell including a steering element having a vertically-oriented p-i-n junction, and a carbon nanotube fabric. The steering element and the carbon nanotube fabric are arranged electrically in series, and the entire memory cell is formed above a substrate. Other aspects are also provided.

Abstract: Disclosed herein is a resistive switching device having an amorphous layer comprised of an insulating silicon-containing material and a conducting material. The amorphous layer may be disposed between two or more electrodes and be capable of switching between at least two resistance states. Circuits and memory devices including resistive switching devices are also disclosed, and a composition of matter involving an insulating silicon-containing material and a conducting material comprising between 5 and 40 percent by molar percentage of the composition is disclosed herein as well. Also disclosed herein are methods for switching the resistance of an amorphous material.

Abstract: A semiconductor device is provided which includes a bottom electrode contact formed on a substrate, and a dielectric layer formed on the bottom electrode contact. The device further includes a heating element formed in the dielectric layer, wherein the heating element is disposed between two air gaps separating the heating element from the dielectric layer, and a phase change element formed on the heating element, wherein the phase change element includes a substantially amorphous background and an active region, the active region capable of changing phase between amorphous and crystalline. A method of forming such a device is also provided.

Abstract: A phase change memory device includes a plurality of word lines, a plurality of bit lines disposed to be crossed with the plurality of word lines, switching devices disposed at intersections of the plurality of word lines and the plurality of bit lines, heating electrodes connected to the switching devices respectively, heat absorbing layers disposed between adjacent heating electrodes, and phase change layers formed on the heating electrodes and the heat absorbing layers and extended in the same direction of the bit line.

Abstract: Various embodiments of the present invention are directed to electronic devices, which combine reconfigurable diode rectifying states with nonvolatile memristive switching. In one aspect, an electronic device (210,230,240) comprises an active region (212) sandwiched between a first electrode (104) and a second electrode (106). The active region includes two or more semiconductor layers and at least one dopant that is capable of being selectively positioned within the active region to control the flow of charge carriers through the device.

Abstract: A phase-change memory device includes a lower electrode; and at least two phase-change memory cells sharing the lower electrode. Another phase-change memory device includes a heating layer having a smaller contact area with a phase-change material layer and a greater contact area with a PN diode structure.

Abstract: A phase change memory device including a phase change material layer having phase change nano particles and a method of fabricating the same are provided. The phase change memory device may include a first electrode and a second electrode facing each other, a phase change material layer containing phase change nano particles interposed between the first electrode and the second electrode and/or a switching device electrically connected to the first electrode. The phase change material layer may include an insulating material.

Abstract: A PCM device has the composition GexTeyNzAm deposited onto a substrate, where x is about 40% to about 60%, y is about 30% to about 49%, and z is about 5% to about 20% and more preferably about 5% to about 40%. The component represented as A is optional and representative of an element of Sb, Sn, In, Ga, or Zn, and m is up to about 15%. The composition is in the form of a film, and the nitrogen allows for the substantially conformal deposition of the film onto the substrate. A CVD process for depositing the PCM comprises delivering a Ge-based precursor and a Te-based precursor in vapor form to a CVD chamber, heating and pressurizing the chamber, and depositing the film onto a substrate. In making a phase change device using this process, the film is annealed and polished.

Abstract: An electrically actuated device (10) comprises an active region (30) disposed between a first electrode (12) and a second electrode (14); 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: A switching element includes: a first electrode supplying metal ions; a second electrode less ionizable than the first electrode; and an ion conducting layer arranged between the first electrode and the second electrode and containing a metal oxide that can conduct the metal ions. The ion conducting layer includes two or more layers of different types, and one of the ion conducting layers that is closest to the first electrode has a larger diffusion coefficient for the metal ions than that of the other ion conducting layer(s).

Abstract: A method for forming a phase change memory cell (PCM) includes forming a heater for the phase change memory and forming a phase change structure electrically coupled to the heater. The forming a heater includes siliciding a material including silicon to form a silicide structure, wherein the heater includes at least a portion of the silicide structure. The phase change structure exhibits a first resistive value when in a first phase state and exhibits a second resistive value when in a second phase state. The silicide structure produces heat when current flows through the silicide structure for changing the phase state of the phase change structure.

Abstract: A nanoscale switching device is provided, comprising: 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 at least one non-conducting layer 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 layer interposed between the first electrode and the second electrode and comprising a highly reactive and highly mobile ionic species that reacts with a component in the switching material to create dopants that are capable of drifting through the non-conducting layer under an electric field, thereby controlling dopant profile by ionic modulation. A crossbar array comprising a plurality of the nanoscale switching devices is also provided, along with a process for making at least one nanoscale switching device.

Abstract: An integrated circuit is fabricated by providing a preprocessed wafer including a first electrode, depositing a dielectric material over the preprocessed wafer, etching an opening in the dielectric material to expose a portion of the first electrode and depositing a first resistivity changing material over exposed portions of the etched dielectric material and the first electrode. The first resistivity changing material is planarized to expose the etched dielectric material. A second resistivity changing material is deposited over the etched dielectric material and the first resistivity changing material, and an electrode material is deposited over the second resistivity changing material.

Abstract: A method for fabricating a phase-change memory cell is described. The method includes forming a dielectric layer (228) on a metal layer (226) above a substrate. A phase-change material layer (230) is formed on the dielectric layer. A contact region (232) is formed, within the dielectric layer, between the phase-change material layer and the metal layer by breaking-down a portion of the dielectric layer.

Abstract: A nonvolatile memory device includes a substrate and a first insulating layer on the substrate. The first insulating layer includes a first opening therein. A lower electrode is provided in the first opening and protrudes from a surface of the first insulating layer outside the first opening. An electrode passivation pattern is provided on a sidewall of the lower electrode that protrudes from the surface of the first insulating layer. A second insulating layer is provided on the first insulating layer and includes a second opening therein at least partially exposing the lower electrode. A variable resistance material layer extends into the second opening to contact the lower electrode. The electrode passivation layer electrically separates the sidewall of the lower electrode from the variable resistance material layer. The electrode passivation pattern is formed of a material having an etching selectivity to that of the second insulating layer. Related fabrication methods are also discussed.

Abstract: A method of forming a phase change material layer includes preparing a substrate having an insulator and a conductor, loading the substrate into a process housing, injecting a deposition gas into the process housing to selectively form a phase change material layer on an exposed surface of the conductor, and unloading the substrate from the process housing, wherein a lifetime of the deposition gas in the process housing is shorter than a time the deposition gas takes to react by thermal energy.

Abstract: A phase change memory is provided, which includes a semiconductor substrate having a first conductive type, buried word lines having a second conductive type, doped semiconductor layers having the first conductive type, memory cells, metal silicide layers, and bit lines. The buried word lines are disposed in the semiconductor substrate. Each buried word line includes a line-shaped main portion extended along a first direction and protrusion portions. Each protrusion portion is connected to one long side of the line-shaped main portion. Each doped semiconductor layer is disposed on one protrusion portion. Each memory cell includes a phase change material layer and is disposed on and electrically connected to one of the doped semiconductor layers. Each metal silicide layer is disposed on one of the line-shaped main portions. Each bit line is connected to memory cells disposed on the word lines in a second direction substantially perpendicular to the first direction.

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 memristive device (100) includes a first and a second electrode (110, 115); a silicon memristive matrix (105) interposed between the first electrode (110) and the second electrode (115); and a mobile dopant species (210, 215) within the silicon memristive matrix (105) which moves in response to a programming electrical field and remains substantially in place after the removal of the programming electrical field.

Abstract: A memristive device includes a first electrode and a second electrode crossing the first electrode at a non-zero angle. An active region is disposed between the first and second electrodes. The active region has defects therein. Graphene or graphite is disposed between the active region and the first electrode and/or between the active region and the second electrode.

Abstract: A phase change memory includes a volume of phase change material disposed between, and coupled to, two electrodes, with the composition of a region of at least one of the two electrodes or phase change material having been compositionally altered to reduce the programmed volume of the phase change material.

Abstract: A memory device includes: a memory layer that is isolated for each memory cell and stores information by a variation of a resistance value; an ion source layer that is formed to be isolated for each memory cell and to be laminated on the memory layer, and contains at least one kind of element selected from Cu, Ag, Zn, Al and Zr and at least one kind of element selected from Te, S and Se; an insulation layer that isolates the memory layer and the ion source layer for each memory cell; and a diffusion preventing barrier that is provided at a periphery of the memory layer and the ion source layer of each memory cell to prevent the diffusion of the element.

Abstract: To provide a variable resistance element capable of preventing the interface resistance, in a side of the variable resistance element in which resistance change is not allowed, from changing to high resistance due to applied voltage. The variable resistance element is configured by providing a variable resistance film (265) between a first electrode (280) and a second electrode (250), the oxygen concentration within the film of the variable resistance film (265) is high at the side of an interface with the second electrode (250) (high-concentration variable resistance layer (260)) and low at the side of an interface with the first electrode (280) (low-concentration variable resistance layer (270)), and the junction surface area between the low-concentration variable resistance layer (270) and the first electrode (280) is larger than the interface surface area between the high-concentration variable resistance layer (260) and the second electrode (250).