Abstract: Provided is a hollow cathode sputtering target comprising an inner bottom face having a surface roughness of Ra?1.0 ?m, and preferably Ra?0.5 ?m. This hollow cathode sputtering target has superior sputter film evenness (uniformity), generates few arcing and particles, is capable of suppressing the peeling of the redeposited film on the bottom face, and has superior deposition characteristics.

Abstract: Provided is a tantalum sputtering target manufactured by working a molten and cast tantalum ingot or billet through forging, annealing and rolling, wherein the structure of the tantalum target comprises a non-recrystallized structure. The tantalum sputtering target having a high deposition speed and excellent uniformity of film, producing less arcings and particles and having excellent film forming properties, and the method capable of stably manufacturing the target can be provided by improving and devising plastic working steps such as forging and rolling, and the heat treatment step.

Abstract: Provided is a manufacturing method of high purity oxide powder including the steps of subjecting a raw material such as Zn-containing scrap to acid leaching or electrolytic extraction, thereafter performing solvent extraction and activated carbon treatment thereto in order to remove impurities, neutralizing the resultant solution freed of impurities with an alkaline solution to obtain zinc hydroxide, and firing the zinc hydroxide to obtain zinc oxide. Provided are high purity zinc oxide efficiently freed of impurities, in particular C, Cl, S and Pb impurities, at low cost and the manufacturing method thereof; a target manufactured by firing the high purity zinc oxide; and a high purity zinc oxide thin film obtained by the sputtering the target.

Abstract: The present invention provides a Ni—Pt alloy superior in workability containing Pt in a content of 0.1 to 20 wt % and having a Vickers hardness of 40 to 90, and a target comprising the Ni—Pt alloy. The present invention also provides a manufacturing method of Ni—Pt alloy superior in workability comprising a step of subjecting a raw material Ni having a purity of 3N level to electrochemical dissolution, a step of neutralizing the electrolytically leached solution with ammonia, a step of removing impurities through filtration with activated carbon, a step of blowing carbon dioxide into the resultant solution to form nickel carbonate and exposing the resultant product to a reducing atmosphere to prepare high purity Ni powder, a step of leaching a raw material Pt having a purity of 3N level with acid, a step of subjecting the leached solution to electrolysis to prepare high purity electrodeposited Pt, and a step of dissolving the resultant high purity Ni powder and high purity electrodeposited Pt.

Abstract: The present invention relates to a nickel alloy sputtering target comprising 1 to 30 at % of Cu; 2 to 25 at % of at least one element selected from among V, Cr, Al, Si, Ti and Mo; remnant Ni and unavoidable impurities so as to inhibit the Sn diffusion between a solder bump and a substrate layer or a pad. Provided are a nickel alloy sputtering target and a nickel alloy thin film for forming a barrier layer having excellent wettability with the Pb-free Sn solder or Sn—Pb solder bump, and capable of inhibiting the diffusion of Sn being a soldering component and effectively preventing the reaction with the substrate layer upon forming a Pb-free Sn solder or Sn—Pb solder bump on a substrate such as a semiconductor wafer or electronic circuit or a substrate layer or pad of the wiring or electrode formed thereon.

Abstract: Provided is a copper or copper alloy target/copper alloy backing plate assembly in which the anti-eddy current characteristics and other characteristics required in a magnetron sputtering target are simultaneously pursued in a well balanced manner. This copper or copper alloy target/copper alloy backing plate assembly is used for magnetron sputtering, and the copper alloy backing plate is formed from low beryllium copper alloy or Cu—Ni—Si-based alloy. Further, with this copper or copper alloy target/copper alloy backing plate assembly, the copper alloy backing plate has electrical conductivity of 35 to 60% (IACS), and 0.2% proof stress of 400 to 850 MPa.

Abstract: Provided are high purity copper sulfate wherein the content of Ag impurities is 1 wtppm or less, and having a purity of 99.99 wt % or higher, and a manufacturing method of high purity copper sulfate including the steps of dissolving crude copper sulfate crystals or copper metal, and subjecting this to active carbon treatment or solvent extraction and active carbon treatment in order to realize recrystallization. The present invention aims to provide a manufacturing method of high purity copper sulfate capable of efficiently removing impurities at a low cost by dissolving commercially available copper sulfate crystals in purified water or acid and thereafter subjecting this to the refining process, and high purity copper sulfate obtained thereby.

Abstract: It is an object of the present invention to provide a semiconductor wafer on which a thin, smooth, uniform and good adhesive electroless plating layer that can be suitable for a seed layer is formed, and to provide an electroless plating method which is suitable for use in the manufacture of such a semiconductor wafer. A semiconductor wafer is coated with a silane coupling agent which has a functional group that is able to capture a metal, and is further coated with an organic-solvent solution of a palladium compound such as palladium chloride or the like. Afterward, the wafer is electroless plated. As a result of such an electroless plating method, a semiconductor wafer having a thickness of 70 to 5000 angstroms and a mean surface roughness Ra of 10 to 100 angstroms can be obtained.

Abstract: A tantalum sputtering target, wherein when the sum of the overall crystalline orientation is 1 on a tantalum target surface, the area ratio of crystals having any orientation among (100), (111), (110) does not exceed 0.5. Thus, obtained is a tantalum sputtering target having superior deposition properties where the deposition speed is high, film evenness (uniformity) is superior, and generation of arcings or particles is reduced.

Abstract: Provided is a manufacturing method of high purity hafnium including the steps of making aqueous solution of chloride of hafnium, thereafter removing zirconium therefrom via solvent extraction, performing neutralization treatment to obtain hafnium oxide, further performing chlorination to obtain hafnium chloride, obtaining hafnium sponge via reducing said hafnium chloride, and performing electron beam melting to the hafnium sponge in order to obtain a hafnium ingot, as well as a high purity hafnium material obtained thereby and a target and thin film formed from such material. The present invention relates to a high purity hafnium material with reduced zirconium content contained in the hafnium, a target and thin film formed from such material, and the manufacturing method thereof, and provides efficient and stable manufacturing technology, a high purity hafnium material obtained according to such manufacturing technology, and a target and high purity hafnium thin film formed from such material.

Abstract: Provided are a high purity Ni—V alloy, high purity Ni—V alloy target and high purity Ni—V alloy thin film wherein the purity of the Ni—V alloy excluding Ni, V and gas components is 99.9 wt % or higher, and the V content variation among ingots, targets or thin films is within 0.4%. With these high purity Ni—V alloy, high purity Ni—V alloy target and high purity Ni—V alloy thin film having a purity of 99.9 wt % or higher, the variation among ingots, targets or thin films is small, the etching property is improved, and isotopic elements such as U and Th that emit alpha particles having an adverse effect on microcircuits in a semiconductor device are reduced rigorously. And further provided is a manufacturing method of such high purity Ni—V alloy capable of effectively reducing the foregoing impurities.

Abstract: It is an object of the present invention to obtain a low-profile electrolytic copper foil with a small surface roughness on the side of the rough surface (the opposite side from the lustrous surface) in the manufacture of an electrolytic copper foil using a cathode drum, and more particularly to obtain an electrolytic copper foil which allows fine patterning, and which is superior in terms of elongation and tensile strength at ordinary temperatures and high temperatures. Furthermore, it is an object of the present invention to obtain a copper electrolytic solution for this purpose. This copper electrolytic solution contains as additives an organo-sulfur compound and a quaternary amine compound with a specific skeleton.

Abstract: The present invention relates to high purity hafnium having a purity of 4N or higher excluding zirconium and gas components and an oxygen content of 40 wtppm or less, and a target and thin film formed from such high purity hafnium, and high purity hafnium having a purity of 4N or higher excluding zirconium and gas components and in which the content of sulfur and phosphorus is respectively 10 wtppm or less. The present invention also relates to a high purity hafnium material which uses a hafnium sponge with reduced zirconium as the raw material, and in which the content of oxygen, sulfur and phosphorus containing in the hafnium is reduced, as well as to a target and thin film formed from such material, and to the manufacturing method of high purity hafnium. Thereby provided is efficient and stable manufacturing technology which enables the manufacture of a high purity hafnium material, and a target and thin film formed from such material.

Abstract: It is an object of the present invention to provide a non-gelling solid silane coupling agent which enhances adhesion of a resin composition to metals and so forth when added to the resin composition, and which has excellent storage stability and molten fluidity. The present invention is a non-gelling, pulverizable, solid silane coupling agent composition composed of a reaction product of the following components.

Abstract: Provided is a hafnium alloy target containing either or both of Zr and Ti in a gross amount of 100 wtppm-10 wt % in Hf, wherein the average crystal grain size is 1-100 ?m, the impurities of Fe, Cr and Ni are respectively 1 wtppm or less, and the habit plane ratio of the plane {002} and three planes {103}, {014} and {015} lying within 350 from {002} is 55% or greater, and the variation in the total sum of the intensity ratios of these four planes depending on locations is 20% or less. As a result, obtained is a hafnium alloy target having favorable deposition property and deposition speed, which generates few particles, and which is suitable for forming a high dielectric gate insulation film such as HfO or HfON film, and the manufacturing method thereof.

Abstract: There is provided a composition for functioning as an effective additive for an epoxy resin that is a solid at room temperature and has a high storage stability, and a method thereof. The composition of the present invention is a basic silane coupling agent organic carboxylate composition obtained by first synthesizing an organic carboxylate of a basic silane coupling agent by reacting a basic silane coupling agent and an organic carboxylic acid, and subsequently heating and mixing the organic carboxylate of the basic silane coupling agent with a compound exhibiting a good affinity for the basic silane coupling agent or organic carboxylic acid and having a softening point or melting point of 40° C. or greater.

Abstract: An epitaxial growth method forming a semiconductor thin film including a heterojunction of a group III-V compound semiconductor by means of molecular beam epitaxy. The method is configured to include: a first step of irradiating a molecular beam of at least one of group III elements and a molecular beam of a first group V element to form a first compound semiconductor layer; a second step of stopping the irradiation of the molecular beam of the group III element and the molecular beam of the first group V element to halt growth until an amount of the first group V element supplied is reduced to 1/10 or less of a supply of the first group V element in the first step; and a third step of irradiating a molecular beam of at least one of the group III elements and a molecular beam of a second group V element to form a second compound semiconductor layer, which is different from the first compound semiconductor, on the first compound semiconductor layer.

Abstract: Provided is a sputtering target having a relative density of 80% or more and containing a compound having as its principal component zinc oxide satisfying AXBYO(KaX+KbY)/2(ZnO)m, 1<m, X?m, 0<Y?0.9, X+Y=2, where A and B are respectively different positive elements of trivalence or more, and the valencies thereof are respectively Ka and Kb. Obtained is a ZnO based sputtering target which does not contain ZnS and SiO2, and, upon forming a film via sputtering, is capable of reducing the affect of heating the substrate, of performing high speed deposition, of adjusting the film thickness to be thin, of reducing the generation of particles (dust) and nodules during sputtering, of improving the productivity with small variation in quality, and which has fine crystal grains and a high density of 80% or more, particularly 90% or more.

Abstract: Provided is high purity nickel or nickel alloy target for Magnetron sputtering having superior sputtering film uniformity and in which the magnetic permeability of the target is 100 or more, and this high purity nickel or a nickel alloy target for magnetron sputtering capable of achieving a favorable film uniformity (evenness of film thickness) and superior plasma ignition (firing) even during the manufacturing process employing a 300 mm wafer. The present invention also provides the manufacturing method of such high purity nickel or nickel alloy target.

Abstract: Since a ZnTe-base compound semiconductor crystal was designed so as to have, on a ZnTe-base compound semiconductor layer, an n-type contact layer which includes a superlattice layer having n-type CdSe and n-type ZnTe grown with each other or a ZnCdSeTe-graded layer, it was made possible to raise carrier concentration of the n-type contact layer, and to control the conductivity type in a relatively easy manner. Moreover, formation of a CdSe/ZnTe superlattice layer or a ZnCdSeTe-graded layer between the contact layer and an electrode can prevent electric resistance from being increased due to difference in the energy gaps. Since CdSe and ZnTe, composing the CdSe/ZnTe superlattice or ZnCdSeTe composition-graded layer, have relatively close lattice constants, formation thereof is less likely to adversely affect the crystallinity of the semiconductor crystal, which is advantageous in obtaining the semiconductor crystal with an excellent quality.