PRODUCT IDENTIFICATION
1306-38-3
H.S. CODE
TOXICITY
CLASSIFICATION
Cerium compound, Catalyst, Sunscreening agent
EXTRA NOTES
PHYSICAL AND CHEMICAL PROPERTIES
MELTING POINT
2600 C
SOLUBILITY IN WATER
6 (Mohs)
REFRACTIVE INDEX
EXTERNAL LINKS & GENERAL DESCRIPTION
http://www.nanopartikel.info/
A huge market for nano-structured CeO2 is cleaning and polishing of
silicon wafers, which are required by the electronical industry for ultra modern
chip systems and solar cells. Due to the reaction of CeO2 with the
processed material, it can be removed in a way extremely fine dosed which
enables the manufacturing of ultra smooth surfaces, which pose the basic
prerequisite for miniaturizing circuits. Together with aluminium oxide, cerium
dioxide constitutes the material of first choice in the matter of chemical-mechanical polishing.
Nano-structured cerium
dioxide, among other things, is used as an oxygen-storing diesel additive in
vehicle exhaust catalysts. It still oxidises carbon monoxide and excess
hydrocarbons into CO2 when there is a temporary lack of oxygen in the
exhaust mixture. During that process, CeO2 is reduced to
Ce2O3 that is re-oxidized later as soon as there is enough
oxygen again in the exhaust gases. Aside from its role in exhaust catalysts
where it mainly supports the much more active but also more expensive platinum,
there is also a direct addition to the fuel intended. The cerium dioxide
particles are supposed to reduce the fuel consumption as well as the emission of
soot particles of diesel engines.
In fuel cells with other rare-earth metal oxides coated
CeO2 particles are applied to improve the oxygen ion conductivity and
so to enable reduced operating temperatures.
Moreover, nano-structured
CeO2 poses an ideal UV absorber and is therefore used as an additive
in lacquers and coatings for wood preservatives to enhance their UV stability.
http://www.1911encyclopedia.org/
Three oxides of cerium are known. The sesquioxide, Ce 2 O 3, is obtained by
heating the carbonate in a current of hydrogen. It is a bluish-green powder,
which on exposure rapidly combines with the oxygen of the air. By the addition
of caustic soda to cerous salts, a white
precipitate of cerous hydroxide is formed. Cerium dioxide, Ce02, is produced
when cerium carbonate, nitrate, sulphate or oxalate is heated in air. It is a
white or pale yellow compound, which becomes reddish on heating. Its specific
gravity is 6.739, and its specific heat 0.0877. It is not reduced to the
metallic condition on heating with carbon.
Concentrated sulphuric acid dissolves this oxide, forming a yellowish solution
and ozone. By suspending the precipitated
cerous hydroxide in water and passing chlorine through the solution, a hydrated form of the
dioxide, 2CeO 2.3H 2 O, is obtained, which is readily soluble in nitric and
sulphuric acids, forming ceric salts, and in hydrochloric acid, where it forms
cerous chloride, with liberation of chlorine. A higher hydrated oxide, CeO 3 xH
2 O, is formed by the interaction of cerous sulphate with sodium acetate and
hydrogen peroxide
Local: Cerium is a metallic chemical element in group IIIb of periodic table; symbol Ce, soft, lustrous, ductile, iron-color metal with hexagonal or cubic crystalline structure; atomic number 58; atomic mass 140.12; melting point ca 799 C; boiling point ca 3,426 C; specific gravity 6.77 g/cm3 at 25 C; oxidation state +3 or +4; electronic config. [Xe]4f15d16s1. It is the most abundant rare-earth element and the most reactive next to europium among the lanthanide group. Lanthanide (or lanthanoid) series are the group of rare-earth elements from lanthanum (atomic numbers 57) to 71; their chemical properties are similar to each other. The chemical properties of scandium and yttrium are also similar to the lanthanides; these group are often referred to "rare earth elements".
|
Atomic No. |
Element |
Symbol |
CAS RN |
| 21 | Scandium |
Sc | 7440-20-2 |
| 39 | Yttrium |
Y | 7440-65-5 |
| 57 | Lanthanum | La | 7439-91-0 |
| 58 | Cerium | Ce | 7440-45-1 |
| 59 | Praseodymium | Pr | 7440-10-0 |
| 60 | Neodymium | Nd | 7440-00-8 |
| 61 | Promethium | Pm | 7440-12-2 |
| 62 | Samarium | Sm | 7440-19-9 |
| 63 | Europium | Eu | 7440-53-1 |
| 64 | Gadolinium | Gd | 7440-54-2 |
| 65 | Terbium | Tb | 7440-27-9 |
| 66 | Dysprosium | Dy | 7429-91-6 |
| 67 | Holmium | Ho | 7440-60-0 |
| 68 | Erbium | Er | 7440-52-0 |
| 69 | Thulium | Tm | 7440-30-4 |
| 70 | Ytterbium | Yb | 7440-64-4 |
| 71 | 7440-64-4 | Lu | 7440-64-4 |
Cerium occurs chiefly in the minerals monazite and bastnaesite. The naturally occurring element is made up of the isotopes 136Ce 0.193%, 138Ce 0.250%, 140Ce 88.58%, and 142Ce 11.07% which is a radioactive alpha emitter having a half-life of 5×1015 years. Cerium is slightly harder than lead. It tarnishes rapidly in moist air but not in dry air. It oxidizes slowly in cold water and rapidly in hot water. It reacts rapidly with the solutions of alkalis and concentrated (or dilute) acids. Its oxidation valence is readily transferred form 3 to 4 if compressed or cooled. Its shell orbitals are relatively close between 4f and the outer. with Cerium of valence +3 is referred to as cerous, while with valence 4 is as ceric. Generally cerous salts are yellow to reddish while ceric slats are white. Minute particles of pure cerium or some iron-cerium alloy ignite if scratched and are used as the flint in cigarette and gas lighters. Cerium is used in making lamp mantles as incandescence is formed when burned. Cerium is allied to form malleable iron, harder stainless steel, heat resistant magnesium and aluminium alloys and permanent magnets. It is also used as an opacifier and polisher in the glass industry, in cored carbon arcs to increase the brilliance especially for the motion picture industry, and as a liquid-liquid extraction agent to remove fission products from spent uranium fuel. Cerium compounds include;
- Ceric Oxide CeO2 (CAS RN:1306-38-3): A pale-yellow to white powder; soluble in sulfuric acid, insoluble in dilute acid and water; used in ceramics and as a polish for optical glass. Catalyst for hydrocarbon cracking, styrene production and water-gas shift reaction. Thermal stabilizer for alumina and in chemical regenerating process.
- Ceric Sulfate Ce(SO4)2·xH2O (CAS RN:13590-82-4): Yellow needles forming a basic salt with excess water; used in waterproofing, mildew-proofing, and in dyeing and printing textiles.
- Ceric Ammonium Nitrate (NH4)2Ce(NO3)6 (CAS RN: 16774-21-3): Oxidizer
- Ceric Ammonium Sulfate Ce(NH4)4(SO4)4 (CAS RN: 10378-47-9, Dihydrate): Oxidizer
- Ceric Hydroxide Ce(OH)4 (CAS RN: 12014-56-1)
- Cerous Acetate Ce(OOCCH3)3·1.5H2O (CAS RN: 537-00-8, Sesquihydrate)
- Cerous Bromide: CeBr3 (CAS RN: 14457-87-5, )
- Cerous Carbonate Ce2(CO3)3 (CAS RN: 537-01-9, 5838-16-7)
- Cerous Chloride CeCl3 (CAS RN: 7790-86-5, 19423-76-8, 18618-55-8)
- Cerous Fluoride CeF3: White hexagonal crystals, melting point 1460 C; used in arc carbons to increase the brilliance of carbon-arc lamps.
- Cerous Naphthenate: Used as drier/additive for paints, coatings and inks; catalyst for chemical reactions
- Cerous Nitrate Ce(NO3)3 (CAS RN:10294-41-4, Hydrate)
- Cerous Oxalate: Ce(C2O4)3·xH2O (CAS RN:139-42-4, 15750-47-7): Used in ceramics, glass, phosphors and pyrotechnics
- Cerous Perchlorate CeO9Cl3 (CAS RN: 14017-47-1)
- Cerous Phosphate CeH2O5P (CAS RN:13454-71-2)
- Cerous Silicide CeSi2 (CAS RN:12014-85-6)
- Cerium Stearate Ce(C18H35O2)2 :White, waxy, inert powder, melting point 100-110 C; used in waterproofing compounds and drier for paint and ink.
- Cerous Sulfide Ce2S3 (CAS RN:12014-93-6)
APPEARANCE
PURITY
99.9% min
PARTICLE SIZE
325 mesh
APPEARANCE
PURITY
99.0% min
PARTICLE SIZE
325 mesh