Abstract: A method for fabricating a multi-layer phase change memory device includes forming a phase change memory layer including a plurality of phase change memory elements on a word line formed on a plurality of semiconductor devices on a first semiconductor substrate, each phase change element having a notch formed at an upper surface thereof, forming an access device layer including plurality of access devices on a second semiconductor substrate, each access device having a conductive bump formed thereon, and combining the first and second semiconductor substrates and slidably inserting and locking each conductive bump of the plurality of access devices into each notch of the plurality of phase change memory elements to electrically connect the access devices to the phase change memory elements.

Abstract: A phase change memory device is provided that includes a switching device, a bottom electrode contact in contact with the switching device and a porous spacer formed on the bottom electrode contact.

Abstract: A selenium ink comprising, as initial components: a liquid carrier; a selenium component comprising selenium; and, an organic chalcogenide component having a formula selected from RZ—Z?R? and R2—SH, a Group 1b component and a liquid carrier; wherein Z and Z? are each independently selected from sulfur, selenium and tellurium; wherein R is selected from H, C1-20 alkyl group, a C6-20 aryl group, a C1-20 alkylhydroxy group, an arylether group and an alkylether group; wherein R? and R2 are selected from a C1-20 alkyl group, a C6-20 aryl group, a C1-20 alkylhydroxy group, an arylether group and an alkylether group; wherein the selenium ink comprises ?1 wt % selenium; wherein the selenium ink is a stable dispersion and wherein the selenium ink is hydrazine and hydrazinium free.

Abstract: A selenium/Group 1b ink comprising, as initial components: a selenium component comprising selenium, an organic chalcogenide component having a formula selected from RZ—Z?R? and R2—SH, a Group 1b component and a liquid carrier; wherein Z and Z? are each independently selected from sulfur, selenium and tellurium; wherein R is selected from H, C1-20 alkyl group, a C6-20 aryl group, a C1-20 alkylhydroxy group, an arylether group and an alkylether group; wherein R? and R2 are selected from a C1-20 alkyl group, a C6-20 aryl group, a C1-20 alkylhydroxy group, an arylether group and an alkylether group; and wherein the selenium/Group 1b ink is a stable dispersion.

Abstract: A phase change memory device having a heater that exhibits a temperature dependent resistivity which provides a way of reducing a reset current is presented. The phase change memory device includes a phase change pattern and a heating electrode contacted with the phase change pattern. The heating electrode includes a smart heating electrode such that the smart heating layer is formed of a conduction material that exhibits an increase in resistance as a function of an increase in temperature, i.e., a positive temperature dependent resistivity.

Abstract: Briefly, in accordance with an embodiment of the invention, a memory and a method to manufacture the memory is provided. The memory may include a phase change material over a substrate. The memory may further include a switching material coupled to the phase change material, wherein the switching material comprises a chalcogen other than oxygen and wherein the switching material and the phase change material form portions of a vertical structure over the substrate.

Abstract: A method for manufacturing a compound semiconductor device forms an EB resist layer on first SiN film, performs EB exposure at high dose for recess forming opening and at low dose for eaves removing opening, develops the high dose EB resist pattern to etch the first SiN film, selectively etches the cap layer to form a recess wider than the opening of the first SiN film leaving eaves of SiN, develops the low dose EB resist pattern to form the eaves removing opening, etches the first SiN film to extinguish the eaves, forms second SiN film on the exposed surface, forms a resist pattern having a gate electrode opening on the second SiN film to etch the second SiN film, forms a metal layer to form a gate electrode by lift-off. The SiN film in eaves shape will not be left.

Abstract: Various embodiments described herein provide a memory device including a variable resistance material having a thermally isolating and electrically conductive isolation region arranged between the variable resistance material and an electrode to allow for efficient heating of the variable resistance material by a programming current. An electrically and thermally isolating isolation region may be arranged around the variable resistance material.

Abstract: A method for fabricating a phase change memory device including a plurality of in via phase change memory cells includes forming pillar heaters formed of a conductive material along a contact surface of a substrate corresponding to each of an array of conductive contacts to be connected to access circuitry, forming a dielectric layer along exposed areas of the substrate surrounding the pillar heaters, forming an interlevel dielectric (ILD) layer above the dielectric layer, etching a via to the dielectric layer, each via corresponding to each of pillar heater such that an upper surface of each pillar heater is exposed within each via, recessing each pillar heater, depositing phase change material in each via on each recessed pillar heater, recessing the phase change material within each via, and forming a top electrode within the via on the phase change material.

Abstract: A method of fabricating a phase-change memory cell is described. The cross-sectional area of a contact with a phase-change memory element within the cell is controlled by a width and an exposed length of a bottom electrode. The method allows the formation of very small phase-change memory cells.

Abstract: Disclosed are a phase change RAM device and a method for fabricating a phase change RAM device, which can efficiently lower intensity of current required for changing a phase of a phase change layer. The method includes the steps of providing a semiconductor substrate formed with an insulating interlayer including a tungsten plug, forming a first oxide layer on the semiconductor substrate, forming a pad-type bottom electrode, which makes contact with the tungsten plug, in the first oxide layer, forming a second oxide layer on the first oxide layer including the bottom electrode, and forming a porous polystyrene pattern on the second oxide layer such that a predetermined portion of the second oxide layer corresponding to a center portion of the bottom electrode is covered with the porous polystyrene pattern.

Abstract: A method for fabricating a multi-layer phase change memory device includes forming a phase change memory layer including a plurality of phase change memory elements on a word line formed on a plurality of semiconductor devices on a first semiconductor substrate, each phase change element having a notch formed at an upper surface thereof, forming an access device layer including plurality of access devices on a second semiconductor substrate, each access device having a conductive bump formed thereon, and combining the first and second semiconductor substrates and slidably inserting and locking each conductive bump of the plurality of access devices into each notch of the plurality of phase change memory elements to electrically connect the access devices to the phase change memory elements.

Abstract: A memory device is described using a composite doped phase change material between a first electrode and a second electrode. A memory element of phase change material, such as a chalcogenide, is between the first and second electrodes and has an active region. The phase change material has a first dopant, such as silicon oxide, characterized by tending to segregate from the phase change material on grain boundaries in the active region, and has a second dopant, such as silicon, characterized by causing an increase in recrystallization temperature of, and/or suppressing void formation in, the phase change material in the active region.

Abstract: A method of fabricating a phase change memory element within a semiconductor structure includes etching an opening to an upper surface of a bottom electrode, the opening being formed of a height equal to a height of a metal region at a same layer within the semiconductor structure, depositing phase change material within the opening, recessing the phase change material within the opening, and forming a top electrode on the recessed phase change material.

Abstract: After silicon oxide film (9) is formed on the surface of a semiconductor substrate (1), the silicon oxide film (9) in a region in which a gate insulation film having a small effective thickness is formed is removed using diluted HF and after that, high dielectric constant insulation film (10) is formed on the semiconductor substrate (1). Consequently, two kinds of gate insulation films, namely, a gate insulation film (12) comprised of stacked film of high dielectric constant insulation film (10) and silicon oxide film (9) and gate insulation film (11) comprised of the high dielectric constant insulation film (10) are formed on the semiconductor substrate (1).

Abstract: Provided is a thin film transistor (TFT) which uses CIS (CuInSe2), including Se, which is a chalcogen-based material, and can provide a rectifying function, and electric and optical switching functions of a diode. The TFT according to the present invention includes, a substrate, a gate electrode formed on a portion of the substrate, an insulating layer covering the substrate and a gate electrode, a plurality of CIS (CuInSe2) films formed on the insulating layer so as to cover the region where the gate electrode is formed; and source/drain regions separated from each other so as to comprise a trench exposing a portion of a surface of the CIS films.

Abstract: A phase change memory device is presented that has a lower electrode contact that has a gradient resistance profile ranging from a lower resistive lower end to a higher resistive upper end. The phase change memory device includes a semiconductor substrate, a lower electrode contact, and a phase change pattern. The semiconductor substrate has a switching device. The lower electrode contact is formed on the switching device and has a specific resistance which gradually increases from a lower part to an upper part of the lower electrode contact. The phase change pattern layer is formed on the lower electrode contact.

Abstract: Disclosed herein is a semiconductor memory device, including: a first electrode formed on a substrate; an ion source layer formed on an upper layer of the first electrode; and a second electrode formed on an upper layer of the ion source layer. Resistance change type memory cells in each of which either a surface of the first electrode or a surface of the ion source layer is oxidized to form a resistance change type memory layer in an interface between the first electrode and the ion source interface are arranged in a array.

Abstract: A selenium ink comprising a chemical compound having a formula RZ-Sex-Z?R? stably dispersed in a liquid carrier is provided, wherein the selenium ink is hydrazine free and hydrazinium free. Also provided are methods of preparing the selenium ink and of using the selenium ink to deposit selenium on a substrate for use in the manufacture of a variety of chalcogenide containing semiconductor materials, such as, thin film transistors (TFTs), light emitting diodes (LEDs); and photoresponsive devices (e.g., electrophotography (e.g., laser printers and copiers), rectifiers, photographic exposure meters and photovoltaic cells) and chalcogenide containing phase change memory materials.

Abstract: A memory cell device includes a memory cell access layer, a dielectric material over the memory cell access layer, a memory material structure within the dielectric material, and a top electrode in electrical contact with the memory material structure. The memory material structure has upper and lower memory material portions and a memory material element therebetween. The lower memory material layer is in electrical contact with a bottom electrode. The lower memory material layer has an average lateral dimension. The memory material element defines an electrical property state change region therein and has a minimum lateral dimension which is substantially less than the average lateral dimension. In some examples the memory material element is a tapered structure with the electrical property state change region at the junction of the memory material element and the lower memory material layer.

Abstract: A memory cell described herein includes a memory element comprising programmable resistance memory material overlying a conductive contact. An insulator element includes a pipe shaped portion extending from the conductive contact into the memory element, the pipe shaped portion having proximal and distal ends and an inside surface defining an interior, the proximal end adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end to the distal end, the bottom electrode having a top surface contacting the memory element adjacent the distal end at a first contact surface. A top electrode is separated from the distal end of the pipe shaped portion by the memory element and contacts the memory element at a second contact surface, the second contact surface having a surface area greater than that of the first contact surface.

Abstract: A memory device comprising a first pan-shaped electrode having a side wall with a top side, a second pan-shaped electrode having a side wall with a top side and an insulating wall between the first side wall and the second side wall. The insulating wall has a thickness between the first and second side walls near the respective top sides. A bridge of memory material crosses the insulating wall, and defines an inter-electrode path between the first and second electrodes across the insulating wall. An array of such memory cells is provided. The bridges of memory material have sub-lithographic dimensions.

Abstract: A phase change memory and method for fabricating the same are provided. The phase change memory element includes: a substrate; rectangle-shaped dielectric patterns formed on the substrate and parallel with each other; electric conductive patterns partially covering a first sidewall and the top surface of the dielectric pattern and the substrate to expose the first sidewall and a second sidewall of the dielectric pattern, wherein the electric conductive patterns covering the same dielectric pattern are apart from each other; a phase change spacer formed on the substrate and directly in contact with the exposed first and second sidewalls of the dielectric patterns, wherein the two adjacent electric conductive patterns covering the same dielectric pattern are electrically connected by the phase change spacer; and a dielectric layer formed on the substrate.

Abstract: A memory cell structure, including a substrate having a via therein bound at first and second ends thereof by electrodes. The via is coated on side surfaces thereof with GST material defining a core that is hollow or at least partially filled with material, e.g., germanium or dielectric material. One or more of such memory cell structures may be integrated in a phase change memory device. The memory cell structure can be fabricated in a substrate containing a via closed at one end thereof with a bottom electrode, by conformally coating GST material on sidewall surface of the via and surface of the bottom electrode enclosing the via, to form an open core volume bounded by the GST material, optionally at least partially filling the open core volume with germanium or dielectric material, annealing the GST material film, and forming a top electrode at an upper portion of the via.

Abstract: A memory cell structure and method for forming the same. The method includes forming a pore within a dielectric layer. The pore is formed over the center of an electrically conducting bottom electrode. The method includes depositing a thermally insulating layer along at least one sidewall of the pore. The thermally insulating layer isolates heat from phase change current to the volume of the pore. In one embodiment phase change material is deposited within the pore and the volume of the thermally insulating layer. In another embodiment a pore electrode is formed within the pore and the volume of the thermally insulating layer, with the phase change material being deposited above the pore electrode. The method also includes forming an electrically conducting top electrode above the phase change material.

Abstract: A phase change memory device having a strain transistor and a method of making the same are presented. The phase change memory device includes a semiconductor substrate, a junction word line, switching diodes, and a strain transistor. The semiconductor substrate includes a cell area and a core/peri area. The junction word line is formed in the cell area of the semiconductor substrate and includes a strain stress supplying layer doped with impurities. The switching diodes are electrically coupled to the junction word line. The strain transistor is formed in the core/peri area of the substrate and acts as a driving transistor.

Abstract: A phase change memory device having partially confined heating electrodes capable of reducing thermal disturbances between adjacent memory cells is presented. The phase change memory device includes a plurality of active regions, a plurality of switching elements, a plurality of heating electrodes, and a plurality of phase change structure lines. The active regions being linear and parallel to each other. The switching elements are coupled to the active regions. The heating electrodes are on and coupled to the switching elements. The phase change structure lines are coupled to the heating electrodes such that the phase change structure lines are substantially vertical to the active regions. The phase change structure lines includes a plurality of plugs projecting downwards that couple to overlapped portions of the heating electrodes.

Abstract: A phase change memory device having an improved word line resistance and a fabrication method of making the same are presented. The phase change memory device includes a semiconductor substrate, a word line, an interlayer insulation film, a strapping line, a plurality of current paths, a switching element, and a phase change variable resistor. The word line is formed in a cell area of the semiconductor substrate. The interlayer insulation film formed on the word line. The strapping line is formed on the interlayer insulation film such that the strapping line overlaps on top of the word line. The current paths electrically connect together the word line with the strapping line. The switching element is electrically connected to the strapping line. The phase change variable resistor is electrically connected to the switching element.

Abstract: A method of forming a memory device, such as a PCRAM, including selecting a chalcogenide glass backbone material for a resistance variable memory function and devices formed using such a method.

Abstract: A memory device having a phase change material element with a modified stoichiometry in the active region does not exhibit drift in set state resistance. A method for manufacturing the memory device includes first manufacturing an integrated circuit including an array of phase change memory cells with bodies of phase change material having a bulk stoichiometry; and then applying forming current to the phase change memory cells in the array to change the bulk stoichiometry in active regions of the bodies of phase change material to the modified stoichiometry, without disturbing the bulk stoichiometry outside the active regions. The bulk stoichiometry is characterized by stability under the thermodynamic conditions outside the active region, while the modified stoichiometry is characterized by stability under the thermodynamic conditions inside the active region.

Abstract: The present invention, in one embodiment, provides a memory device that includes a phase change memory cell; a first electrode; and a layer of filamentary resistor material positioned between the phase change memory cell and the first electrode, wherein at least one bistable conductive filamentary pathway is present in at least a portion of the layer of filamentary resistor material that provides electrical communication between the phase change memory cell and the first electrode.

Abstract: Antimony, germanium and tellurium precursors useful for CVD/ALD of corresponding metal-containing thin films are described, along with compositions including such precursors, methods of making such precursors, and films and microelectronic device products manufactured using such precursors, as well as corresponding manufacturing methods. The precursors of the invention are useful for forming germanium-antimony-tellurium (GST) films and microelectronic device products, such as phase change memory devices, including such films.

Abstract: Methods for fabricating highly compact PCM memory devices are described herein. The methods may include forming a bipolar junction transistor (BJT) structure on a substrate including creating a base of the BJT structure on the substrate and creating an emitter of the BJT structure on top of the base opposite of the substrate. A heating element may then be constructed on the emitter of the BJT structure, wherein the heating element includes a material to generate heat when provided with an electrical current from the emitter. A phase change material (PCM) cell may then be built on the heating element opposite of the BJT structure.

Abstract: The present invention provides a method of making a Cu—In—Ga sputtering target by melting Cu, In and Ga, Cu and In or Cu and Ga to form a uniform melt with a pre-determined stoichiometry, which melt is sprayed to cause sprayed uniform melt particles to solidify into Cu—In—Ga particles with the pre-determined stoichiometry. The sputtering target is then made using the Cu—In—Ga particles.

Abstract: A phase change device includes a native oxide grown on the surface of a first phase change alloy layer. The native oxide is punched through during the first electrical pulse applied between the device electrodes. An aperture created in the native oxide limit a region of localized heating during the device programming. A method for the phase change device fabrication includes a native oxide formation.

Abstract: To include a superlattice laminate having laminated thereon a first crystal layer of which crystal lattice is a cubic crystal and in which positions of constituent atoms are reversibly replaced by application of energy, and a second crystal layer having a composition different from that of the first crystal layer, and an orientation layer that is an underlaying layer of the superlattice laminate and causes a laminated surface of the first crystal layer to be (111)-orientated. According to the present invention, the laminated surface of the first crystal layer can be (111)-orientated by using the orientation layer as an underlaying layer. In the first crystal layer of which laminated surface is (111)-orientated, a crystal structure reversibly changes when a relatively low energy is applied. Therefore, characteristics of a superlattice device having this crystal layer can be enhanced.

Abstract: A memory includes multiple layers of deposited memory material. An etch is performed on at least one layer of deposited memory material prior to the deposition of a subsequent layer of memory material.

Abstract: A phase-change memory device has a plurality of first wiring lines; a plurality of memory cells that are provided on the plurality of first wiring lines; a plurality of second wiring lines that are provided on the plurality of memory cells, respectively; and an interlayer insulating film that is formed between the plurality of first wiring lines and the plurality of second wiring lines and insulates the plurality of first wiring lines from the plurality of second wiring lines; wherein each of the memory cells includes a heat source element that is supplied with a current and generates heat and a phase-change element that is changed to an amorphous state or a crystalline state according to a cooling speed after being heated by the heat source element, a resistance value of the phase-change element varying with the change in the state, and wherein a void is formed between the two adjacent memory cells in the interlayer insulating film.

Abstract: A method of forming a phase change material which having germanium and tellurium therein includes depositing a germanium-containing material over a substrate. Such material includes elemental-form germanium. A gaseous tellurium-comprising precursor is flowed to the germanium-comprising material and tellurium is removed from the gaseous precursor to react with the elemental-form germanium in the germanium-comprising material to form a germanium and tellurium-comprising compound of a phase change material over the substrate. Other implementations are disclosed.

Abstract: A phase change memory device and a method of manufacture are provided. The phase change memory device includes a phase change layer electrically coupled to a top electrode and a bottom electrode, the phase change layer comprising a phase change material. A mask layer is formed overlying the phase change layer. A first sealing layer is formed overlying the mask layer, and a second sealing layer is formed overlying the first sealing layer.

Abstract: Methods of fabricating integrated circuit memory cells and integrated circuit memory cells are disclosed. Formation of an integrated circuit memory cell include forming a first electrode on a substrate. An insulation layer is formed on the substrate with an opening that exposes at least a portion of a first electrode. An amorphous variable resistivity material is formed on the first electrode and extends away from the first electrode along sidewalls of the opening. A crystalline variable resistivity material is formed in the opening on the amorphous variable resistivity material. A second electrode is formed on the crystalline variable resistivity material.

Abstract: An integrated semiconductor structure includes a heterojunction bipolar transistor and a Schottky diode. The structure has a substrate, the heterojunction bipolar transistor overlying and contacting the substrate, wherein the heterojunction bipolar transistor includes a transistor collector layer, and a Schottky diode overlying the substrate and overlying the transistor collector layer. The Schottky diode includes a Schottky diode barrier layer structure that desirably is not of the same material, doping, and thickness as the transistor collector layer.

Abstract: A chemical-mechanical polishing (CMP) method of polishing a phase-change material and a method of fabricating a phase-change memory, the CMP method including forming the phase-change material on an activation surface of a semiconductor wafer, and performing a CMP process on the phase-change material using a polishing pad, wherein the performing the CMP process includes reducing a change in the composition of the phase-change material by adjusting, within a predetermined range, a temperature of a region where the semiconductor wafer and the polishing pad contact each other.

Abstract: An active material electronic device is described with a containment layer. The device includes an active chalcogenide, pnictide, or phase-change material in electrical communication with an upper and lower electrode. The device includes a containment layer formed over the active material that prevents escape of volatilized matter from the active material when the device is exposed to high temperatures during fabrication or operation. The containment layer further prevents chemical contamination of the active material by protecting it from reactive species in the processing or ambient environment. The containment layer and intermediate layers formed between the active material and containment layer are formed at temperatures sufficiently low to prevent volatilization of the active material. Once the containment layer is formed, the device may be subjected to high temperature or chemically aggressive environments without impairing the compositional or structural integrity of the active material.

Abstract: Provided is a method of forming a phase change memory device, the method including washing and rinsing a phase change device structure. A phase change material layer may be formed on a semiconductor substrate. The phase change material layer may be etched so as to form a phase change device structure. The semiconductor substrate on which the phase change device structure is formed may be washed using a washing solution including a reducing agent containing fluorine (F), a pH controller, a dissolution agent and water. In addition, the semiconductor substrate on which the washing is performed may be rinsed.

Abstract: A phase change memory is manufactured by providing a substrate including a layer of phase-change material, forming a damascene pattern on the layer of phase-change material, and forming both a top electrode and a bit line in the damascene pattern.

Abstract: In a method of forming a chalcogenide compound target, a first powder including germanium carbide or germanium is prepared, and a second powder including antimony carbide or antimony is prepared. A third powder including tellurium carbide or tellurium is prepared. A powder mixture is formed by mixing the first to the third powders. After a shaped is formed body by molding the powder mixture. The chalcogenide compound target is obtained by sintering the powder mixture. The chalcogenide compound target may include a chalcogenide compound that contains carbon and metal, or carbon, metal and nitrogen considering contents of carbon, metal and nitrogen, so that a phase-change material layer formed using the chalcogenide compound target may stable phase transition, enhanced crystallized temperature and increased resistance. A phase-change memory device including the phase-change material layer may have reduced set resistance and driving current while improving durability and sensing margin.

Abstract: A variable resistance memory cell structure and a method of forming it. The method includes forming a first electrode, forming an insulating material over the first electrode, forming a via in the insulating material to expose a surface of the first electrode, forming a heater material within the via using gas cluster ion beams, forming a variable resistance material within the via, and forming a second electrode such that the heater material and variable resistance material are provided between the first and second electrodes.

Abstract: A method of manufacturing a semiconductor device includes forming a phase change material pattern on a top surface of an insulating layer including an opening and in the opening, and forming a compressive layer compressing the phase change material pattern on the phase change material pattern.

Abstract: A copper indium gallium selenide photovoltaic cell can include a substrate having a transparent conductive oxide layer. The copper indium gallium selenide can be deposited using sputtering and vapor transport deposition.