Abstract: A first conductive electrode material is formed on a substrate. Chalcogenide comprising material is formed thereover. The chalcogenide material comprises AxSey. A silver comprising layer is formed over the chalcogenide material. The silver is irradiated effective to break a chalcogenide bond of the chalcogenide material at an interface of the silver comprising layer and chalcogenide material and diffuse at least some of the silver into the chalcogenide material. After the irradiating, the chalcogenide material outer surface is exposed to an iodine comprising fluid effective to reduce roughness of the chalcogenide material outer surface from what it was prior to the exposing. After the exposing,. a second conductive electrode material is deposited over the chalcogenide material, and which is continuous and completely covering at least over the chalcogenide material, and the second conductive electrode material is formed into an electrode of the device.

Abstract: A method for controlling silver doping of a chalcogenide glass in a resistance variable memory element is disclosed herein. The method includes forming a thin metal containing layer having a thickness of less than about 250 Angstroms over a second chalcogenide glass layer, formed over a first metal containing layer, formed over a first chalcogenide glass layer. The thin metal containing layer preferably is a silver layer. An electrode may be formed over the thin silver layer. The electrode preferably does not contain silver.

Abstract: A PCRAM memory device having a chalcogenide glass layer, preferably comprising antimony selenide having a stoichometric formula of about Sb2Se3, and a metal-chalcogenide layer and methods of forming such a memory device.

Abstract: A memory device including at least one first memory element comprising a first layer of amorphous carbon over at least one second memory element comprising a second layer of amorphous carbon. The device also includes at least one first conductive layer common to the at least one first and the at least one second memory elements.

Abstract: The invention provides a method of forming a resistance variable memory element and the resulting element. The method includes forming an insulating layer having an opening therein; forming a metal containing layer recessed in the opening; forming a resistance variable material in the opening and over the metal containing layer; and processing the resistance variable material and metal containing layer to produce a resistance variable material containing a diffused metal within the opening.

Abstract: A memory device including at least one first memory element comprising a first layer of amorphous carbon over at least one second memory element comprising a second layer of amorphous carbon. The device also includes at least one first conductive layer common to the at least one first and the at least one second memory elements.

Abstract: A low-volatility or non-volatility memory device utilizing zero field splitting properties to store data. In response to an electrical pulse or a light pulse, in the absence of any externally applied magnetic field, the host material can switch between stable energy-absorbing states based on the zero field splitting properties of the metal ions and the surrounding host material. The invention also includes a device and method for the storage of multiple bits in a single cell using a plurality of metal ion species in a single host material.

Abstract: Methods and apparatus for providing a memory device that can be programmed a limited number of times. According to exemplary embodiments, a memory device and its method of formation provide a first electrode, a second electrode and a layer of a chalcogenide or germanium comprising material between the first electrode and the second electrode. The memory device further includes a tin-chalcogenide layer between the chalcogenide or germanium comprising material layer and the second electrode.

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 one embodiment of the invention, a resistance variable memory element is provided having at least one silver-selenide layer in between two glass layers, wherein at least one of the glass layers is a chalcogenide glass, preferably having a GexSe100?x composition. According to another embodiment of the invention, a resistance variable memory element is provided having at least one silver-selenide layer in between chalcogenide glass layers and further having a silver layer above at least one of said chalcogenide glass layers and a conductive adhesion layer above said silver layer.

Abstract: A resistance variable memory element with improved data retention and switching characteristics switched between resistance memory states upon the application of write pulses having the same polarity. The resistance variable memory element can be provided having at least one silver-selenide layer in between glass layers, the glass layers are a chalcogenide glass having a GexSe100?x composition.

Abstract: A first conductive electrode material is formed on a substrate. Chalcogenide comprising material is formed thereover. The chalcogenide material comprises AxSey. A silver comprising layer is formed over the chalcogenide material. The silver is irradiated effective to break a chalcogenide bond of the chalcogenide material at an interface of the silver comprising layer and chalcogenide material and diffuse at least some of the silver into the chalcogenide material. After the irradiating, the chalcogenide material outer surface is exposed to an iodine comprising fluid effective to reduce roughness of the chalcogenide material outer surface from what it was prior to the exposing. After the exposing, a second conductive electrode material is deposited over the chalcogenide material, and which is continuous and completely covering at least over the chalcogenide material, and the second conductive electrode material is formed into an electrode of the device.

Abstract: A memory element having a first electrode is provided, wherein the first electrode comprises at least one conductive nanostructure. The memory element further includes a second electrode and a resistance variable material layer between the first and second electrodes. The first electrode electrically is coupled to the resistance variable material. Methods for forming the memory element are also provided.

Abstract: A semiconductor processing method includes forming an antireflective coating comprising Ge and Se over a substrate to be patterned. Photoresist is formed over the antireflective coating. The photoresist is exposed to actinic radiation effective to pattern the photoresist. The antireflective coating reduces reflection of actinic radiation during the exposing than would otherwise occur under identical conditions in the absence of the antireflective coating. After the exposing, the substrate is patterned through openings in the photoresist and the antireflective coating using the photoresist and the antireflective coating as a mask. In one implementation, after patterning the substrate, the photoresist and the antireflective coating are chemically etched substantially completely from the substrate using a single etching chemistry.

Abstract: A method and apparatus for providing a resistance variable memory element with improved data retention and switching characteristics have at least one metal-containing layer and a silver layer disposed between glass layers. At least one of the glass layers is a chalcogenide glass, preferably having a GexSe100?x composition.

Abstract: The invention relates to the fabrication of a resistance variable material cell or programmable metallization cell. The processes described herein can form a metal-rich metal chalcogenide, such as, for example, silver-rich silver selenide. Advantageously, the processes can form the metal-rich metal chalcogenide without the use of photodoping techniques and without direct deposition of the metal. For example, the process can remove selenium from silver selenide. One embodiment of the process implants oxygen to silver selenide to form selenium oxide. The selenium oxide is then removed by annealing, which results in silver-rich silver selenide. Advantageously, the processes can dope silver into a variety of materials, including non-transparent materials, with relatively high uniformity and with relatively precise control.

Abstract: The invention relates to a DNR (differential negative resistance) exhibiting device that can be programmed to store information as readable current amplitudes and to methods of making such a device. The stored data is semi-volatile. Generally, information written to a device in accordance with the invention can maintain its memory for a matter of minutes, hours, or days before a refresh is necessary. The power requirements of the device are far reduced compared to DRAM. The memory function of the device is highly stable, repeatable, and predictable. The device can be produced in a variety of ways.

Abstract: A resistance variable memory element and a method for forming the same. The memory element has an amorphous carbon layer between first and second electrodes. A metal-containing layer is formed between the amorphous carbon layer and the second electrode.

Abstract: The present invention is related to methods and apparatus to produce a memory cell or resistance variable material with improved data retention characteristics and higher switching speeds. In a memory cell according to an embodiment of the present invention, silver selenide and a chalcogenide glass, such as germanium selenide (GexSe(1?x)) are combined in an active layer, which supports the formation of conductive pathways in the presence of an electric potential applied between electrodes. Advantageously, embodiments of the present invention can be fabricated with relatively wide ranges for the thicknesses of the silver selenide and glass layers.

Abstract: The invention provides a method of forming a resistance variable memory element and the resulting element. The method includes forming an insulating layer having an opening therein; forming a metal containing layer recessed in the opening; forming a resistance variable material in the opening and over the metal containing layer; and processing the resistance variable material and metal containing layer to produce a resistance variable material containing a diffused metal within the opening.

Abstract: The invention includes a device displaying differential negative resistance characterized by a current-versus-voltage profile having a peak-to-valley ratio of at least about 9. The invention also includes a semiconductor construction comprising a substrate, and a first layer over the substrate. The first layer comprises Ge and one or more of S, Te and Se. A second layer is over the first layer. The second layer comprises M and A, where M is a transition metal and A is one or more of O, S, Te and Se. A third layer is over the second layer, and comprises Ge and one or more of S, Te and Se. The first, second and third layers are together incorporated into an assembly displaying differential negative resistance. Additionally, the invention includes methodology for forming assemblies displaying differential negative resistance, such as tunnel diode assemblies.