Abstract: A method for fabricating high efficiency CIGS solar cells including the deposition of Ga concentrations (Ga/(Ga+In)=0.25?0.66) from sputtering targets containing Ga concentrations between about 25 atomic % and about 66 atomic %. Further, the method includes a high temperature selenization process integrated with a high temperature anneal process that results in high efficiency.

Abstract: A bistable resistance random access memory is described for enhancing the data retention in a resistance random access memory member. A dielectric member, e.g. the bottom dielectric member, underlies the resistance random access memory member which improves the SET/RESET window in the retention of information. The deposition of the bottom dielectric member is carried out by a plasma-enhanced chemical vapor deposition or by high-density-plasma chemical vapor deposition. One suitable material for constructing the bottom dielectric member is a silicon oxide. The bistable resistance random access memory includes a bottom dielectric member disposed between a resistance random access member and a bottom electrode or bottom contact plug. Additional layers including a bit line, a top contact plug, and a top electrode disposed over the top surface of the resistance random access memory member. Sides of the top electrode and the resistance random access memory member are substantially aligned with each other.

Abstract: A slurry composition for chemical mechanical polishing (CMP) of a phase-change memory device is provided. The slurry composition comprises deionized water and iron or an iron compound. The slurry composition can achieve high polishing rate on a phase-change memory device and improved polishing selectivity between a phase-change memory material and a polish stop layer (e.g., a silicon oxide film), can minimize the occurrence of processing imperfections (e.g., dishing and erosion), and can lower the etch rate on a phase-change memory material to provide a high-quality polished surface. Further provided is a method for polishing a phase-change memory device using the slurry composition.

Abstract: This invention includes processes for making a photovoltaic absorber layer having a predetermined stoichiometry on a substrate by depositing a precursor having the predetermined stoichiometry onto the substrate and converting the deposited precursor into a photovoltaic absorber material. This invention further includes processes for making a photovoltaic absorber layer having a predetermined stoichiometry on a substrate by (a) providing a polymeric precursor having the predetermined stoichiometry; (b) providing a substrate; (c) depositing the precursor onto the substrate; and (d) heating the substrate.

Abstract: This invention relates to methods and articles using compounds, polymeric compounds, and compositions used to prepare semiconductor and optoelectronic materials and devices including thin film and band gap materials. This invention provides a range of compounds, polymeric compounds, compositions, materials and methods directed ultimately toward photovoltaic applications, transparent conductive materials, as well as devices and systems for energy conversion, including solar cells. In particular, this invention relates to polymeric precursor compounds and precursor materials for preparing photovoltaic layers. A compound may contain repeating units {MB(ER)(ER)} and {MA(ER)(ER)}, wherein MA is Ag, each MB is In or Ga, each E is S, Se, or Te, and each R is independently selected, for each occurrence, from alkyl, aryl, heteroaryl, alkenyl, amido, silyl, and inorganic and organic ligands.

Abstract: A device that incorporates teachings of the present disclosure may include, for example, a memory array having a first array of nanotubes, a second array of nanotubes, and a resistive change material located between the first and second array of nanotubes. Other embodiments are disclosed.

Abstract: A tandem solar cell includes: a substrate; a front electrode disposed on the substrate; a back electrode disposed opposite to the front electrode on the substrate; a first cell disposed below the front electrode and including a first buffer layer and a first light absorption layer; and a second cell disposed above the back electrode and including a second light absorption layer and a second buffer layer. The first light absorption layer includes a CuGaSeS layer and a CuGaSe layer, and the second light absorption layer includes a semiconductor compound selected from the group consisting of CuInSe2, CuInGaSe2, CuInSeS, CuInGaSeS and any combinations thereof. The CuGaSeS layer of the first light absorption layer is disposed closer than the CuGaSe layer of the first light absorption layer to the front electrode.

Abstract: A method of fabricating a solar cell involves electroplating a Group IIB-VIA material as a first or sub-layer over a junction partner layer, and then forming a second layer, also of a Group IIB-VIA material over the sub-layer. Both the sub-layer and the second layer comprise Te. The electroplating is performed at relatively low temperatures, as for example, below 100° C. Forming the sub-layer by low temperature electroplating produces a small grained compact film that protects the interface between the sub-layer and the junction partner during the formation of the second layer. The second layer may be formed by physical vapor deposition or ink deposition. A solar cell has a first layer of a stoichiometric Group IIB-VIA material formed on a CdS film, and a second layer of a Group IIB-V1A material. Both the first and second layers contain Te. The first layer may comprise CdTe with a grain size small than 0.5 microns and the second layer may comprise CdTe with a grin size in the range of 1-5 microns.

Abstract: In an integrated structure of a CIS based thin film solar cell obtained by stacking an light absorbing layer, a high-resistance buffer layer, and a window layer in that order, a first buffer layer adjoining the light absorbing layer is made of a compound containing cadmium (Cd), zinc (Zn), or indium (In), a second buffer layer adjoining the first buffer layer is made of a zinc oxide-based thin film, a third buffer layer is formed to cover the end face exposed by forming an interconnect pattern in the light absorbing layer, the first buffer layer, and the second buffer layer and the top end surface of the second buffer layer, and the third buffer layer is made of a zinc oxide-based thin film.

Abstract: Highly ordered anodic TiO2 nanotube arrays fabricated by electrochemical anodization and sensitized with dye to yield dye-sensitized TiO2 nanotube solar cells is described. With inorganic compound (such as TiCl4) treatment, in conjunction with oxygen plasma exposure under optimized conditions, dye-sensitized TiO2 nanotube solar cells produced using TiO2 nanotube arrays exhibited a pronounced power conversion efficiency.

Abstract: A thin film and a method of making a thin film. The thin film comprises a patterned substrate, a smooth film of electric field tuned quantum dots solution positioned on the patterned substrate, and a thin layer of metal positioned on the thin film. The method begins by drop-casting a quantum dots solution onto a patterned substrate to create a thin film. While the quantum dots solution is drying, a linearly increasing electric filed is applied. The thin film is then placed in a deposition chamber and a thin layer of metal is deposited onto the thin film. Also included are a method of measuring the photoinduced charge transfer (PCT) rate in a quantum dot nanocomposite film and methods of forming a Shottky barrier on a transparent ITO electrode of a quantum dot film.

Abstract: A back contact configuration for a CIGS-type photovoltaic device is provided. According to certain examples, the back contact configuration includes an optical matching layer and/or portion of or including MoSe2 having a thickness substantially corresponding to maxima of absorption of reflected light in CIGS-type absorbers used in certain photovoltaic devices. Certain example methods for making the back contact configuration wherein a thickness of the MoSe2 layer and/or portion can be controlled to be within thickness ranges that correspond to maxima of CIGS light absorption for reflected solar light are also provided.

Abstract: A photovoltaic device (e.g., solar cell) includes: a front substrate (e.g., glass substrate); a semiconductor absorber film; a back contact including a first conductive layer of or including copper (Cu) and a second conductive layer of or including molybdenum (Mo); and a rear substrate (e.g., glass substrate). The first conductive layer of or including copper is located between at least the rear substrate and the second conductive layer of or including molybdenum, and wherein the semiconductor absorber film is located between at least the back contact and the front substrate.

Abstract: A compound semiconductor thin film solar cell is provided, which includes a light-absorbing layer made of a compound semiconductor and a buffer layer formed on the light-absorbing layer. The buffer layer is formed with use of an ink containing nanoparticles each containing at least a metal element and an element of Group 16.

Abstract: Disclosed are a high density CIS thin film and a method of manufacturing the same, which includes coating CIS nanopowders, CIGS nanopowders or CZTS nanopowders on a substrate by non-vacuum coating, followed by heat treatment with cavities between the nanopowders filled with filling elements such as copper, indium, gallium, zinc, tin, and the like. The high density CIS thin film is applied to a photo-absorption layer of a thin film solar cell, thereby providing a highly efficient thin film solar cell.

Abstract: In a method for forming a light absorber layer (4) of a thin film solar cell, the absorber layer is formed from a plurality of sub-layers each of which is formed by preparing a plurality of mixtures containing Cu, Se, In and Ga in a liquid medium, a composition ratio of In to Ga being progressively increased from one mixture to another, the mixtures optionally including a mixture containing no In or Ga; applying a layer of one of the mixtures onto a back electrode layer (3) formed on a substrate (2); drying the applied layer of the mixture; and rapidly baking the dried layer of the mixture. By forming the absorber layer with a plurality of thin absorber sub-layers each having a controlled band gap, a solar cell having a large surface area can be fabricated at low cost and the efficiency of the solar cell can be improved by forming a favorable band gap gradient structure.

Abstract: In one embodiment, a method includes depositing a photoactive layer onto a first substrate, depositing a contact layer onto the photoactive layer, attaching a second substrate onto the contact layer, and removing the first substrate from the photoactive layer, contact layer, and second substrate.

Abstract: To obtain high-quality chalcopyrite particles having a small particle size using a relatively inexpensive raw material in a simple and easy process in which complicated equipment (such as vacuum equipment) is not necessary. Provided is a method for producing a compound having a chalcopyrite structure represented by a compositional formula: ABC2, the method including: a step of dissolving a Group 11 element A, a Group 13 element B, and a Group 16 element C of the periodic table in a solvent to prepare a solution; and a step of contacting the solution with a reducing agent.

Abstract: A novel 2 step solid source deposition (2SSS) method to form an absorber layer in the manufacture for CIGS solar modules. 2-step refers to a first step of deposition of metals followed by second step of selenization of the metal stack. Metals are first deposited and then selenized in an adjacent chamber. Differential pumping is used to control egress of Se vapor into the sputtering region and prevent contamination of the targets. Products made by the method demonstrate comparable quality and performance to those produced by current processing techniques. The 2SSS method provides means for attaining improved uniformity of large area films which improves yield and cost-effectiveness.

Abstract: A method for preparing a Group 1a-1b-3a-6a material using 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 photovoltaic element (110) for converting electromagnetic radiation into electrical energy is provided, which has a tandem cell structure.

Abstract: Described herein is a method and liquid-based precursor composition for depositing a multicomponent film. In one embodiment, the method and compositions described herein are used to deposit Germanium Tellurium (GeTe), Antimony Tellurium (SbTe), Antimony Germanium (SbGe), Germanium Antimony Tellurium (GST), Indium Antimony Tellurium (IST), Silver Indium Antimony Tellurium (AIST), Cadmium Telluride (CdTe), Cadmium Selenide (CdSe), Zinc Telluride (ZnTe), Zinc Selenide (ZnSe), Copper indium gallium selenide (CIGS) films or other tellurium and selenium based metal compounds for phase change memory and photovoltaic devices.

Abstract: A method for producing a high yield of high quality, low size distribution, and size tunable semiconductor nanocrystals. The method produces III-V, II-VI, II-V, IV-VI, IV, ternary, quarternary, and quinary semiconductor nanocrystals (quantum dots) using a catalyst assisted two-phase reaction.

Abstract: A method for producing a continuous film of at least one solar cell module comprises the steps of depositing (8) a material forming a release layer onto a surrogate substrate in the form of a belt (1) being moved in a continuous loop, depositing (12, 14, 17) layers forming a solar cell film onto said release layer, applying (25) a first protective plastic layer onto the solar cell film, separating (31) a film including at least said solar cell film and said plastic layer attached thereto from said belt, and applying (35) a second protective plastic layer on the side of said film separated opposite to said first protective plastic layer.

Abstract: A method for manufacturing a CIGS thin film photovoltaic device includes forming a back contact layer on a substrate, forming an Se-rich layer on the back contact layer, forming a precursor layer on the Se-rich layer by depositing copper, gallium and indium resulting in a first interim structure, annealing or selenizing the first interim structure, thereby forming Cu/Se, Ga/Se or CIGS compounds along the interface between the back contact layer and the precursor layer and resulting in a second interim structure, and selenizing the second interim structure, thereby converting the precursor layer into a CIGS absorber layer on the back contact layer.

Abstract: A method of manufacturing (AgxCu1-x)2ZnSn(SySe1-y)4 thin films, the method comprising: providing a thin film comprising Ag and/or Cu, the thin film further comprising Zn; and annealing the thin film in an atmosphere comprising S and/or Se, and further comprising Sn.

Abstract: The present invention relates to a method for fabricating a thin layer made of a alloy and having photovoltaic properties. The method according to the invention comprises first steps of: a) depositing an adaptation layer (MO) on a substrate (SUB), b) depositing at least one layer (SEED) comprising at least elements I and/or III, on said adaptation layer. The adaptation layer is deposited under near vacuum conditions and step b) comprises a first operation of depositing a first layer of I and/or III elements, under same conditions as the deposition of the adaptation layer, without exposing to air the adaptation layer.

Abstract: A method for manufacturing polycarbonate solar cells. The method is designed to adapt many techniques used in the compact disc manufacturing industry to the manufacture of polycarbonate solar cells. The method comprises: creating a polycarbonate substrate for a solar cell; depositing a low resistivity cathodic contact layer on the polycarbonate substrate; depositing a photonic energy absorbing layer with a sputter chamber comprising a quaternary CIGS sputter target; using a modulated high intensity pulsed xenon flashlamp; depositing a buffer layer; depositing a highly resistive transmissive intrinsic layer; depositing a transmissive contact oxide window layer; adding anodic contacts to one of the layers; depositing an anti-reflective coating layer; and encapsulating the solar cell to provide environmental protection.

Abstract: Photovoltaic devices and techniques for enhancing efficiency thereof are provided. In one aspect, a photovoltaic device is provided. The photovoltaic device comprises a photocell having a photoactive layer and a non-photoactive layer adjacent to the photoactive layer so as to form a heterojunction between the photoactive layer and the non-photoactive layer; and a plurality of high-aspect-ratio nanostructures on one or more surfaces of the photoactive layer. The plurality of high-aspect-ratio nanostructures are configured to act as a scattering media for incident light. The plurality of high-aspect-ratio nanostructures can also be configured to create an optical resonance effect in the incident light.

Abstract: A phase-change memory device includes a word line on a substrate and a phase-change memory cell on the word line and comprising a phase-change material pattern. The device also includes a non-uniform conductivity layer pattern comprising a conductive region on the phase-change material pattern and a non-conductive region contiguous therewith. The device further includes a bit line on the conductive region of the non-uniform conductivity layer pattern. In some embodiments, the phase-change memory cell may further include a diode on the word line, a heating electrode on the diode and wherein the phase-change material layer is disposed on the heating electrode. An ohmic contact layer and a contact plug may be disposed between the diode and the heating electrode.

Abstract: This invention relates to thin film photovoltaic materials containing aluminum, as well as methods for making materials using polymeric precursor compounds. This invention provides a range of compounds, polymeric compounds, compositions, materials and methods directed ultimately toward photovoltaic applications, devices and systems for energy conversion, and solar cells. This invention further relates to methods for making CA(I,G,A)S, CAIGAS, A(I,G,A)S, AIGAS, C(I,G,A)S, and CIGAS thin film materials by providing one or more polymeric precursor compounds or inks thereof, providing a substrate, depositing the compounds or inks onto the substrate; and heating the substrate.

Abstract: Sulfur-containing chalcogenide absorbers in thin film solar cell are manufactured by sequential sputtering or co-sputtering targets, one of which contains a sulfur compound, onto a substrate and then annealing the substrate. The anneal is performed in a non-sulfur containing environment and avoids the use of hazardous hydrogen sulfide gas. A sulfurized chalcogenide is formed having a sulfur concentration gradient.

Abstract: A phase change memory element and method of forming the same. The memory element includes first and second electrodes. A first layer of phase change material is between the first and second electrodes. A second layer including a metal-chalcogenide material is also between the first and second electrodes and is one of a phase change material and a conductive material. An insulating layer is between the first and second layers. There is at least one opening in the insulating layer providing contact between the first and second layers.

Abstract: This invention includes processes for making a photovoltaic absorber layer having a predetermined stoichiometry on a substrate by depositing a precursor having the predetermined stoichiometry onto the substrate and converting the deposited precursor into a photovoltaic absorber material. This invention further includes processes for making a photovoltaic absorber layer having a predetermined stoichiometry on a substrate by (a) providing a polymeric precursor having the predetermined stoichiometry; (b) providing a substrate; (c) depositing the precursor onto the substrate; and (d) heating the substrate.

Abstract: Methods of manufacturing a phase-change memory device and a semiconductor device are provided. The method of manufacturing the phase-change memory device includes forming a switching device layer, an ohmic contact layer, and a hard mask layer on a semiconductor substrate, patterning the hard mask layer to form a hard mask pattern, etching the ohmic layer and the switching layer using the hard mask pattern to form a pattern structure including an ohmic contact pattern, a switching device pattern, and the hard mask pattern, selectively oxidizing a surface of the pattern structure, forming an insulating layer to bury the pattern structure, and selectively removing the hard mask pattern other than the oxidized surface thereof to form a contact hole.

Abstract: In a method for producing a photoelectric conversion device including a light absorption layer made of a CIGS-based compound semiconductor, a vacancy formation process for forming Cu vacancies in a surface layer of the light absorption layer in a layered member that is composed of a lower electrode and the light absorption layer deposited on a substrate is performed, and after then, a pn junction is formed in the surface layer of the light absorption layer.

Abstract: This invention relates to inks comprising molecular precursors to copper indium gallium sulfide/selenide (CIGS/Se) and a plurality of particles. The inks are useful for preparing coatings and films of CIGS/Se on substrates. Such films are useful in the preparation of photovoltaic devices. This invention also relates to processes for preparing coated substrates and films and also to processes for making photovoltaic devices.

Abstract: Methods and devices are provided for improved photovoltaic devices. Non-vacuum deposition of transparent conductive electrodes in a roll-to-roll manufacturing environment is disclosed. In one embodiment, a method is provided for forming a photovoltaic device. The method comprises processing a precursor layer in one or more steps to form a photovoltaic absorber layer; depositing a smoothing layer to fill gaps and depression in the absorber layer to reduce a roughness of the absorber layer; adding an insulating layer over the smooth layer; and forming a web-like layer of conductive material over the insulating layer. By way of nonlimiting example, the web-like layer of conductive material comprises a plurality of carbon nanotubes. In some embodiments, the absorber layer is a group IB-IIIA-VIA absorber layer.

Abstract: Erosion of chalcogenides in phase change memories using ovonic threshold switch selectors can be reduced by controlling columnar morphology in electrodes used in the ovonic threshold switch. The columnar morphology may cause cracks to occur which allow etchants used to etch the ovonic threshold switch to sneak through the ovonic threshold switch and to attack chalcogenides, either in the switch or in the memory element. In one embodiment, the electrode may be split into two metal nitride layers separated by an intervening metal layer.

Abstract: A device comprises a heater, a dielectric layer, a phase-change element, and a capping layer. The dielectric layer is disposed at least partially on the heater and defines an opening having a lower portion and an upper portion. The phase-change element occupies the lower portion of the opening and is in thermal contact with the heater. The capping layer overlies the phase-change element and occupies the upper portion of the opening. At least a fraction of the phase-change element is operative to change between lower and higher electrical resistance states in response to an application of an electrical signal to the heater.

Abstract: A method for forming a back contact for a photovoltaic cell that includes at least one semiconductor layer is provided. The method includes applying a continuous film of a chemically active material on a surface of the semiconductor layer and activating the chemically active material such that the activated material etches the surface of the semiconductor layer. The method further includes removing the continuous film of the activated material from the photovoltaic cell and depositing a metal contact layer on the etched surface of the semiconductor layer.

Abstract: A photovoltaic cell can include a heterojunction between semiconductor layers. The first semiconductor layer can include a III-V compound semiconductor, the first semiconductor layer positioned over a transparent conductive layer. A second semiconductor layer can include a II-VI compound semiconductor, the second semiconductor layer positioned between the first semiconductor layer and a back metal contact.

Abstract: A germanium (Ge) compound is provided. The Ge compound has a chemical formula GeR1xR2y. “R1” is an alkyl group, and “R2” is one of hydrogen, amino group, allyl group and vinyl group. “x” is greater than zero and less than 4, and the sum of “x” and “y” is equal to 4. Methods of forming the Ge compound, methods of fabricating a phase change memory device using the Ge compound, and phase change memory devices fabricated using the Ge compound are also provided.

Abstract: A switching element for a memory device includes a base layer including a plurality of line-type trenches. First insulation patterns are formed on the base layer excluding the trenches. First diode portions are formed on the bottoms of the trenches in the form of a thin film. Second insulation patterns are formed on the first diode portions and are spaced apart from each other to form holes in the trenches having the first diode portions provided therein. Square pillar-shaped second diode portions are formed in the holes over the first diode portions.

Abstract: An industrial production line is presented to fabricate CIGS thin film solar cells on continuous flexible substrates in roll-to-roll processes. It provides an entire solution including procedures and related equipments from starting blank substrates to completed solar cells that can be used to fabricate solar modules. This production line contains some core apparatuses, such as a modular electroplating system to deposit CIGS materials, a modular thermal reactor to annealing the CIGS films, and a chemical bath deposition reactor to coat CdS buffer layer, are recently invented by the present inventor. The present production line can be conveniently used to prepare the CIGS thin film solar cells with high efficiency but low cost.

Abstract: Provided is a method for manufacturing a photovoltaic cell in which a light absorption layer is formed by promoting chalcogenation.

Abstract: Described are an apparatus and a method for depositing a thin film on a web. The method includes depositing a first layer of a composite metal onto a web. A first selenium layer is deposited onto the first layer and the web is heated to selenize the first layer. Subsequently, a second layer of the composite metal is deposited onto the selenized first layer and a second selenium layer is deposited onto the second layer. The web is then heated to selenize the second layer. The composition of each composite metal layer can be varied to achieve desired bandgap gradients and other film properties. Segregation of gallium and indium is substantially reduced or eliminated because each incremental layer is selenized before the next incremental layer is deposited. The method can be implemented in production systems to deposit CIGS films on metal and plastic foils.

Abstract: Systems and methods for solar cells with CIS and CIGS films made by reacting evaporated copper chlorides with selenium are provided. In one embodiment, a method for fabricating a thin film device comprises: providing a semiconductor film comprising indium (In) and selenium (Se) upon a substrate; heating the substrate and the semiconductor film to a desired temperature; and performing a mass transport through vapor transport of a copper chloride vapor and se vapor to the semiconductor film within a reaction chamber.

Abstract: The present invention provides a reaction chamber to monitor a metal ion in solution during the formation of a metal-sulfide layer on a substrate. The reaction chamber houses a solution of an ammonium ion, a metal ion and a buffer. The reaction chamber includes an anion-selective electrode in the solution to monitor the metal ion that measures the metal ion during metal-ammonium complex formation, metal-thiourea complex formation, metal sulfide composition formation, metal sulfide layer formation or a combination thereof.

Abstract: A photovoltaic cell is fabricated onto a polyimide film using an unbalanced RF magnetron sputtering process. The sputtering process includes the addition of 0.05% to 0.5% oxygen to an inert gas stream. Portions of the photovoltaic cell are exposed to an elevated temperature CdCl2 treatment which is at or below the glass transition temperature of the polyimide film.