Abstract: A sample separation apparatus including a porous, or rough, capillary column. The porous capillary column includes a matrix which defines pores, and may be formed rough surface of hemispherical grain silicon. The capillary column is defined in a surface of a substrate, such as silicon. The sample separation apparatus may include a stationary phase or a capture substrate disposed on the surfaces thereof. The sample separation apparatus may also include a detector positioned proximate the capillary column. A variation of the sample separation apparatus includes an electrode proximate each end of the capillary column. The sample separation apparatus may be employed to effect various types of chromatographic separation, electrophoretic separation, and analyte identification.

Abstract: An integrated programmable conductor memory cell and diode device in an integrated circuit comprises a diode and a glass electrolyte element, the glass electrolyte element having metal ions mixed or dissolved therein and being able to selectively form a conductive pathway under the influence of an applied voltage. In one embodiment, both the diode and the memory cell comprise a chalcogenide glass, such as germanium selenide (e.g., Ge2Se8 or Ge25Se75). The first diode element comprises a chalcogenide glass layer having a first conductivity type, the second diode element comprises a chalcogenide glass layer doped with an element such as bismuth and having a second conductivity type opposite to the first conductivity type and the memory cell comprises a chalcogenide glass element with silver ions therein. In another embodiment, the diode comprises silicon and there is a diffusion barrier layer between the diode and the chalcogenide glass memory element.

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: In one implementation, a plasma etching method comprises forming a GexSey chalcogenide comprising layer over a substrate. A mask comprising an organic masking material is formed over the GexSey chalcogenide comprising layer. The mask comprises a sidewall. At least prior to plasma etching the GexSey comprising layer, the sidewall of the mask is exposed to a fluorine comprising material. After said exposing, the GexSey chalcogenide comprising layer is plasma etched using the mask and a hydrogen containing etching gas. The plasma etching forms a substantially vertical sidewall of the GexSey chalcogenide comprising layer which is aligned with a lateral outermost extent of the sidewall of the mask.

Abstract: A deposition method includes, at a first temperature, contacting a substrate with a surface activation agent and adsorbing a first layer over the substrate. At a second temperature greater than the first temperature, the first layer may be contacted with a first precursor, chemisorbing a second layer at least one monolayer thick over the substrate. The first layer may enhance a chemisorption rate of the first precursor compared to the substrate without the surface activation agent adsorbed thereon. One deposition apparatus includes a deposition chamber with a precursor gas dispenser in a contacting zone and a cooling gas dispenser in a cooling zone. A substrate chuck moves by linear translational motion from the contacting zone to the cooling zone. The substrate chuck includes a substrate lift that positions a deposition substrate at an elevation above a heated surface of the substrate chuck when dispensing a cooling gas or surface activation agent.

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 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: In one implementation, a non-volatile resistance variable device includes a body formed of a voltage or current controlled resistance setable material, and at least two spaced electrodes on the body. The body includes a surface extending from one of the electrodes to the other of the electrodes. The surface has at least one surface striation extending from proximate the one electrode to proximate the other electrode at least when the body of said material is in a highest of selected resistance setable states. In one implementation, a method includes structurally changing a non-volatile device having a body formed of a voltage or current controlled resistance setable material and at least two spaced electrodes on the body. The body has a surface extending from one of the electrodes to the other of the electrodes, and the surface is formed to comprise at least one surface striation extending from proximate the one electrode to proximate the other electrode.

Abstract: Embodiments in accordance with the present invention provide for removing organic materials from substrates, for example substrates employed in the fabrication of integrated circuits, liquid crystal displays and the like. Such embodiments also provide for forming self-limiting oxide layers on oxidizable materials disposed on such substrates where such materials are exposed to the methods of the present invention. The methods of the present invention provide for contacting substrates with a solution of ozone, water and a surfactant, the solution being effective for removing organic materials and forming self-limiting oxide layers on oxidizable materials.

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: An architecture, and its method of formation and operation, containing a high density memory array of semi-volatile or non-volatile memory elements, including, but not limited to, programmable conductive access memory elements. The architecture in one exemplary embodiment has a pair of semi-volatile or non-volatile memory elements which selectively share a bit line through respective first electrodes and access transistors controlled by respective word lines. The memory elements each have a respective second electrode coupled thereto which in cooperation with the bit line access transistors and first electrode, serves to apply read, write and erase signals to the memory element.

Abstract: A method of metal doping a chalcogenide material includes forming a metal over a substrate. A chalcogenide material is formed on the metal. Irradiating is conducted through the chalcogenide material to the metal effective to break a chalcogenide bond of the chalcogenide material at an interface of the metal and chalcogenide material and diffuse at least some of the metal outwardly into the chalcogenide material. A method of metal doping a chalcogenide material includes surrounding exposed outer surfaces of a projecting metal mass with chalcogenide material. Irradiating is conducted through the chalcogenide material to the projecting metal mass effective to break a chalcogenide bond of the chalcogenide material at an interface of the projecting metal mass outer surfaces and diffuse at least some of the projecting metal mass outwardly into the chalcogenide material. In certain aspects, the above implementations are incorporated in methods of forming non-volatile resistance variable devices.

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 switchable circuit device. The device comprises a first conductive layer and a porous silicon matrix over the first conductive layer. A material is dispersed within pores of the porous silicon matrix, and the material has two stable states. A second conductive layer is formed over the porous silicon matrix. A current flow between the first and second conductive layers is influenced by which of the stable states the material is in.

Abstract: A software refreshed memory device comprises a plurality of memory cells that must be periodically refreshed to avoid losing data. Preferably, the memory cells can avoid losing data even though the time interval between successive memory refresh operations is relatively long, as compared to the time interval between successive memory refresh operations in a conventional volatile memory device, such as a DRAM. A processor can perform periodic memory refresh operations by executing a set of memory refresh instructions implemented in software, rather than in hardware. Accordingly, the memory device can advantageously be simplified, because the need for memory refresh circuitry and for a unique refresh control signal are advantageously eliminated. Moreover, the processor executing the memory refresh instructions can typically perform more sophisticated algorithms, as compared to memory refresh circuitry implemented in hardware, for determining when to perform a memory refresh operation.

Abstract: Methods and apparatus for fabricating and cleaning in-process semi-conductor wafers are provided. An in-process wafer is placed within a closed chamber. A reactant gas is incorporated in a liquid solvent to form a “reactant mixture” that is capable of reacting with photoresist material (or other material) on a wafer surface to facilitate removal of the material from the wafer surface. The reactant mixture is condensed on one or more of the in-process wafer surfaces to form a thin film on the surface(s) of the wafer. The solvent in the reactant mixture acts as a transport medium to place the reactant gas on the wafer surface. The reactant gas is then able to react with the photoresist material (or other material) on the in-process wafer surface to effect removal the material. Following reaction of the reactant gas with the photoresist, the thin film of reactant mixture is removed from the wafer surface by flash heating, rinsing, draining, or other suitable means.

Abstract: Apparatus and methods for measuring characteristics of a metallic target as well as other interior surfaces of a sputtering chamber. The apparatus includes a sensor configured to emit an energy beam toward a surface of interest and to detect an energy beam therefrom, the detected energy beam being indicative of parameters of a characteristic of interest of the surface of interest. Quantitative and qualitative characteristics of interest may be determined. A sputtering system including the apparatus and operable according to the methods of the invention is also disclosed.

Abstract: A method for refreshing PCRAM cells programmed to a low resistance state and entire arrays of PCRAM cells uses a simple refresh scheme which does not require separate control and application of discrete refresh voltages to the PCRAM cells in an array. Specifically, the array structure of a PCRAM device is constructed to allow leakage current to flow through each programmed cell in the array to refresh the programmed state. In one embodiment, the leakage current flows across the access device between the anode of the memory element and the bit line to which the cell is connected, for each memory cell in the array which has been programmed to the low resistance state. In another embodiment, the leakage current flows to the programmed cells through a doped substrate or doped regions of a substrate on which each cell is formed. An entire array is refreshed simultaneously by forming each memory element in the array to have one common anode formed as a single cell plate for the array.

Abstract: A method of forming a non-volatile resistance variable device includes forming a first conductive electrode material on a substrate. A metal doped chalcogenide comprising material is formed over the first conductive electrode material. Such comprises the metal and AxBy, where “B” is selected from S, Se and Te and mixtures thereof, and where “A” comprises at least one element which is selected from Group 13, Group 14, Group 15, or Group 17 of the periodic table. In one aspect, the chalcogenide comprising material is exposed to and HNO3 solution. In one aspect the outer surface is oxidized effective to form a layer comprising at least one of an oxide of “A” or an oxide of “B”. In one aspect, a passivating material is formed over the metal doped chalcogenide comprising material. A second conductive electrode material is deposited, and a second conductive electrode material of the device is ultimately formed therefrom.

Abstract: The invention includes a switchable circuit device. The device comprises a first conductive layer and a porous silicon matrix over the first conductive layer. A material is dispersed within pores of the porous silicon matrix, and the material has two stable states. A second conductive layer is formed over the porous silicon matrix. A current flow between the first and second conductive layers is influenced by which of the stable states the material is in.