- LUTETIUM
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- $0.00 / 25kg
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2025-12-29
- CAS:7439-94-3
- Min. Order: 1kg
- Purity: 98%
- Supply Ability: 1000kg
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| | LUTETIUM Chemical Properties |
| Melting point | 1663 °C (lit.) | | Boiling point | 3402 °C (lit.) | | density | 9.84 g/mL at 25 °C (lit.) | | storage temp. | Flammables area | | solubility | soluble in dilute acid solutions | | form | powder | | color | Silver-gray | | Specific Gravity | 9.842 | | PH | 0.5 (20°C in H2O) | | resistivity | 54 μΩ-cm, 20°C | | Water Solubility | Insoluble in water. | | Sensitive | Air & Moisture Sensitive | | Merck | 13,5635 | | Exposure limits | ACGIH: TWA 2 ppm; STEL 4 ppm
OSHA: TWA 2 ppm(5 mg/m3)
NIOSH: IDLH 25 ppm; TWA 2 ppm(5 mg/m3); STEL 4 ppm(10 mg/m3) | | InChI | 1S/Lu | | InChIKey | OHSVLFRHMCKCQY-UHFFFAOYSA-N | | SMILES | [Lu] | | Shear Modulus | 27.2 GPa | | Poissons Ratio | 0.261 | | Hardness, Vickers | 44 | | Bulk Modulus | 47.6 GPa | | CAS DataBase Reference | 7439-94-3(CAS DataBase Reference) | | EPA Substance Registry System | Lutetium (7439-94-3) |
| Hazard Codes | F,Xi | | Risk Statements | 11-36/38 | | Safety Statements | 16-33-36/37/39-26 | | RIDADR | UN 3089 4.1/PG 2 | | WGK Germany | 3 | | TSCA | TSCA listed | | HazardClass | 4.1 | | PackingGroup | III | | Storage Class | 4.1B - Flammable solid hazardous materials | | Hazard Classifications | Flam. Sol. 1 |
| | LUTETIUM Usage And Synthesis |
| Discovery | Lutetium was separated and discovered by Urbain in 1907 using nitric acid. It exists in the earth's crust in minerals and ores and whilst rare is more abundant than gold and silver. Lutetium oxide is used in catalysts in the petroleum industry and Lu -177 the isotope is used in cancer treatments due to its radioactivity. Lutetium atoms are the smallest of all the lanthanides meaning it has the highest melting and boiling points. It is a solid metal at room temperature with a melting point of 1652°c and a boiling point of 3402°c.
| | Chemical Properties | grey powder | | Physical properties | In the last (17th) position in the lanthanide series, lutetium is the heaviest and largestmolecule of all the rare-earths as well as the hardest and most corrosion-resistant. It has asilvery-white color and is somewhat stable under normal atmospheric conditions.
Its melting point is 1,663°C, its boiling point is 3,402°C, and its density is 9.84g/cm3. | | Isotopes | There are a total of 59 isotopes of Lutetium. Only two of these are stable: Lu-175, which makes up 97.41% of all the natural abundance found on Earth. The otheris a long-lived radioisotope (Lu-176) with such a long half-life (4.00×10+10 years) thatit is considered stable: Lu-176 contributes 2.59% to the natural abundance of lutetium. | | Origin of Name | Lutetium’s name is derived from the ancient Latin name for Paris,
France: Lutecia. | | Occurrence | Lutetium is the 60th most abundant element on Earth, and it ranks 15th in the abundanceof the rare-earths. It is one of the rarest of the lanthanide series. It is found in monazite sand(India, Australia, Brazil, South Africa, and Florida), which contains small amounts of all therare-earths. Lutetium is found in the concentration of about 0.0001% in monazite. It is difficultto separate it from other rare-earths by the ion-exchange process. In the pure metallicform, lutetium is difficult to prepare, which makes is very expensive. | | Characteristics | Lutetium has had a number of different names over the years. At one time or another,it was called neoytterbium, lutecium, lutetia, lutetium, and cassiopium. Some scientists inGermany still refer to it as cassiopium.
Lutetium reacts slowly with water and is soluble in weak acids. Its crystals exhibit strongmagnetic properties, which are important to the study of magnetism. | | History | In 1907, Urbain described a process by which Marignac’s ytterbium (1879) could be separated into the two elements, ytterbium (neoytterbium) and lutetium. These elements were identical with “aldebaranium” and “cassiopeium,” independently discovered by von Welsbach about the same time. Charles James of the University of New Hampshire also independently prepared the very pure oxide, lutecia, at this time. The spelling of the element was changed from lutecium to lutetium in 1949. Lutetium occurs in very small amounts in nearly all minerals containing yttrium, and is present in monazite to the extent of about 0.003%, which is a commercial source. The pure metal has been isolated only in recent years and is one of the most difficult to prepare. It can be prepared by the reduction of anhydrous LuCl3 or LuF3 by an alkali or alkaline earth metal. The metal is silvery white and relatively stable in air. While new techniques, including ion-exchange reactions, have been developed to separate the various rare-earth elements, lutetium is still the most costly of all rare earths. It is priced at about $100/g (99.9%). 176Lu occurs naturally (97.41%) with 175Lu (2.59%), which is radioactive with a very long half-life of about 4 × 1010 years. Lutetium has 50 isotopes and isomers that are now recognized. Stable lutetium nuclides, which emit pure beta radiation after thermal neutron activation, can be used as catalysts in cracking, alkylation, hydrogenation, and polymerization. Virtually no other commercial uses have been found yet for lutetium. While lutetium, like other rare-earth metals, is thought to have a low toxicity rating, it should be handled with care until more information is available. | | Uses | Lutetium is the last member of the rare earth series. Unlike most rare earths it lacks a magnetic moment. It also has the smallest metallic radius of any rare earth. It is perhaps the least naturally abundant of the Lanthanides. It is the ideal host for x-ray phosphors because it produces the densest known white material, Lutetium Tantalate (LuTaO4). It is utilized as a dopant in matching lattice parameters of certain substrate garnet crystals, such as Indium-Gallium-Garnet (IGG) crystals due its lack of a magnetic moment.
Lutetium isotopes can data the age of meteorites and are used to target tumors experimentally. Stable lutetium can be used as catalysts in petroleum cracking in refineries and can also be used in alkylation, hydrogenation, and polymerization applications.
Lutetium Metal, is the hardest metal of the rare-earths, used as important additive to some specialty alloy. Stable Lutetium can be used as catalysts in petroleum cracking in refineries and can also be used in alkylation, hydrogenation, and polymerization applications. Lutetium is used as a phosphor in LED light bulbs.
 | | Uses | Because lutetium is difficult to prepare on a large scale, its practical uses are limited. Someof its radioisotopes are used as catalysts in the cracking (refining) process of crude oil, whichproduces lighter fractions such as diesel fuel and gasoline. It can also be used as a catalyst tospeed up the reaction in some hydrogenation processes wherein hydrogen is added to vegetableoils to make more solid products. Some of its isotopes have been used to determine theage of meteorites. | | Uses | Lutetium is used as an additive for special steel, non-ferric alloy, hydrogen storage alloy, also reducer for making other rare Earth metal. Pipe materials of reactor system. Used in Physical Vapor Deposition (PVD) processes, including thermal and electron-beam (e-beam) evaporation, for the preparation of thin films. | | Definition | A silvery element
of the lanthanoid series of metals. It
occurs in association with other lanthanoids.
Lutetium is a very rare lanthanoid
and has few uses.
Symbol: Lu; m.p. 1663°C; b.p. 3395°C;
r.d. 9.84 (25°C); p.n. 71; r.a.m. 174.967. | | Definition | lutetium: Symbol Lu. A silvery metallic element belonging to thelanthanoids; a.n. 71; r.a.m. 174.97;r.d. 9.8404 (20°C); m.p. 1663°C; b.p.3402°C. Lutetium is the least abundantof the elements and the little quantities that are available have been obtained by processing other metals. There are two natural isotopes,lutetium–175 (stable) andlutetium–176 (half-life 2.2×1010years). The element is used as a catalyst.It was first identified by GergesUrbain (1872–1938) in 1907. | | Hazard | Lutetium fluoride is a skin irritant, and its fumes are toxic if inhaled. The dust and powderof the oxides of some rare-earths, including lutetium, are toxic if inhaled or ingested. | | Synthesis | Lutetium minerals are processed as follows. After the ore is crushed, it reacts with hot concentrated sulfuric acid to form water-soluble sulfates of various rare earth elements. Thorium hydroxide will precipitate out and can be removed directly. The remaining solution requires the addition of ammonium oxalate to convert the rare earth elements to insoluble oxalates. After annealing, the oxalate will change to an oxide, which is then dissolved in nitric acid. This removes cerium, the main component, as its oxide is insoluble in nitric acid. Ammonium nitrate can crystallize and separate several rare earth elements, including lutetium, as a double salt. Lutetium can be extracted by ion exchange. In this process, the rare earth element ions are adsorbed onto a suitable ion exchange resin and will be exchanged with hydrogen, ammonium or copper ions in the resin. Lutetium can be washed out individually by utilizing a suitable cooperating agent. To produce lutetium metal, a reduction reaction can be performed with an alkali metal or alkaline earth metal to anhydrous LuCl3 or LuF3.
2 LuCl3 + 3 Ca → 2 Lu + 3 CaCl2
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| | LUTETIUM Preparation Products And Raw materials |
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