Current Category: CN-XB - Rare earths
This document is applicable to high-purity yttrium target materials produced by vacuum casting and powder metallurgy, and is mainly used in fields such as electronic information, coatings, and displays.
This document is applicable to ultra-fine cerium oxide powder with an apparent average particle size of no more than 1 μm, which is produced by chemical methods and used in fields such as catalytic materials, polishing materials, and UV shielding materials.
This document is applicable to high-purity yttrium obtained by purification methods such as vacuum refining, vacuum distillation, and zone melting, and is mainly used in the production of high-purity yttrium targets and their alloy targets, special alloy materials, and coating materials.
This document is applicable to high-purity lanthanum obtained by purification methods such as vacuum refining, electrolytic refining, and zone melting, and is mainly used in the production of lanthanum targets and hydrogen storage materials.
This document applies to lanthanum cerium chloride solid and liquid products obtained by chemical methods from rare earth minerals, which are used as raw materials for the production of petroleum cracking catalysts, rare earth polishing powders, and other rare earth products.
This document is applicable to lanthanum cerium fluoride obtained by chemical methods, which is mainly used in metallurgy and chemical industry, special alloys, preparation of lanthanum cerium metals and their alloys, additives, etc.
This document is applicable to fluoride terbium obtained by chemical methods, which is mainly used for the preparation of metal terbium, terbium-containing alloys, and other purposes.
This document is applicable to erbium fluoride obtained by chemical methods, which is used in the production of erbium metal, erbium alloys, optical fiber doping, laser crystals, and catalysts, etc.
This document is applicable to the determination of the fluorine content in neodymium-iron-boron waste materials. The measurement range (mass fraction) is 0.010% to 1.00%.
This document is applicable to the determination of aluminum, chromium, nickel, and zinc content in rare earth smelting recycling materials from electrolytic and thermal reduction processes. The measurement range for aluminum is 0.020% to 1.50%; and for chromium, nickel, and zinc, it is 0.0050% to 0.10%.
This document contains two methods: X-ray fluorescence spectrometry (Method 1) and inductively coupled plasma emission spectrometry (Method 2). Method 1 is suitable for determining the distribution of 15 rare earth element oxides in praseodymium-neodymium alloy smelting recovery materials, lanthanum-cerium alloy smelting recovery materials, lanthanum reduction recovery materials, and rare earth-iron alloy smelting recovery materials (dysprosium iron, holmium iron, gadolinium iron). Method 2 is suitable for determining the distribution of 15 rare earth element oxides in praseodymium-neodymium alloy smelting recovery materials, lanthanum-cerium alloy smelting recovery materials, lanthanum reduction recovery materials, calcium reduction recovery materials, and rare earth-iron alloy smelting recovery materials (dysprosium iron, holmium iron, gadolinium iron). When the analysis ranges of the two methods overlap, Method 2 shall be used as the arbitration method.
This document is applicable to the determination of the total rare earth content in recycled materials from rare earth pyrometallurgical recovery processes, including electrolytic and thermal reduction processes. This document contains two methods: oxalate weight method (Method 1) and inductively coupled plasma emission spectrometry (Method 2). The determination range (mass fraction) of Method 1 is 5.00% to 90.00%, and the determination range (mass fraction) of Method 2 is 0.50% to 10.00%. When the determination ranges of the two methods overlap, Method 1 shall be used as the arbitration method.