Uranium hexafluoride

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Uranium hexafluoride

Names
IUPAC names Uranium hexafluoride Uranium(VI) fluoride
Identifiers
CAS Number	7783-81-5 Y
ChEBI	CHEBI:30235 Y
ChemSpider	22966 Y
Jmol 3D model	Interactive image
PubChem	24560
RTECS number	YR4720000
UN number	2978 (<1% 235U) 2977 (>1% 235U)
InChI InChI=1S/6FH.U/h6*1H;/q;;;;;;+6/p-6 Y Key: SANRKQGLYCLAFE-UHFFFAOYSA-H Y InChI=1/6FH.U/h6*1H;/q;;;;;;+6/p-6/rF6U/c1-7(2,3,4,5)6 Key: SANRKQGLYCLAFE-IIYYNVFAAT
SMILES F[U](F)(F)(F)(F)F
Properties
Chemical formula	UF6
Molar mass	352.02 g/mol
Appearance	colorless solid
Density	5.09 g/cm3, solid
Melting point	64.052 °C (147.294 °F; 337.202 K) (triple point at 151 kPa[1])
Boiling point	56.5 °C (133.7 °F; 329.6 K) (sublimes)
Solubility in water	Reacts violently
Solubility	soluble in chloroform, CCl4, liquid chlorine and bromine dissolves in nitrobenzene
Structure
Crystal structure	Orthorhombic, oP28
Space group	Pnma, No. 62
Coordination geometry	octahedral (Oh)
Dipole moment	0
Thermochemistry
Std molar entropy (So298)	– solid: −430,4 ± 1,5 J·K−1·mol−1[2] – gaseous: −280,4 ± 1,5 J·K−1·mol−1[2]
Std enthalpy of formation (ΔfHo298)	– solid: −(2197,7 ± 1,8) kJ·mol−1[2] – gaseous: −(2148,1 ± 1,8) kJ·mol−1[2]
Vapor pressure	{{{value}}}
Related compounds
Other anions	Uranium hexachloride
Other cations	Neptunium hexafluoride Plutonium hexafluoride
Related uranium fluorides	Uranium(III) fluoride Uranium(IV) fluoride Uranium(V) fluoride
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Y verify (what is YN ?)
Infobox references

Uranium hexafluoride (UF₆), referred to as "hex" in the nuclear industry, is a compound used in the uranium enrichment process that produces fuel for nuclear reactors and nuclear weapons. It forms solid grey crystals at standard temperature and pressure, is highly toxic, reacts violently with water and is corrosive to most metals. It reacts mildly with aluminium, forming a thin surface layer of AlF₃ that resists further reaction.

Preparation

Milled uranium ore—U₃O₈ or "yellowcake"—is dissolved in nitric acid, yielding a solution of uranyl nitrate UO₂(NO₃)₂. Pure uranyl nitrate is obtained by solvent extraction, then treated with ammonia to produce ammonium diuranate ("ADU", (NH₄)₂U₂O₇). Reduction with hydrogen gives UO₂, which is converted with hydrofluoric acid (HF) to uranium tetrafluoride, UF₄. Oxidation with fluorine yields UF₆.

During nuclear reprocessing, uranium is reacted with chlorine trifluoride to give UF₆:

U + 2 ClF₃ → UF₆ + Cl₂

Properties

Physical properties

At atmospheric pressure, it sublimes at 56.5 °C.^[3]

UF₆ in a glass ampoule.

The solid state structure was determined by neutron diffraction at 77 K and 293 K.^[4][5]

• 

  Ball-and-stick model of the unit cell of uranium hexafluoride^[6]

• 

  Bond lengths and angles of gaseous uranium hexafluoride^[7]

Chemical properties

It has been shown that uranium hexafluoride is an oxidant^[8] and a Lewis acid that is able to bind to fluoride; for instance, the reaction of copper(II) fluoride with uranium hexafluoride in acetonitrile is reported to form copper(II) heptafluorouranate(VI), Cu(UF₇)₂.^[9]

Polymeric uranium(VI) fluorides containing organic cations have been isolated and characterised by X-ray diffraction.^[10]

Application in the nuclear fuel cycle

Phase diagram of UF₆.

UF₆ is used in both of the main uranium enrichment methods — gaseous diffusion and the gas centrifuge method — because it has a triple point at 64.05 °C (147 °F, 337 K) and slightly higher than normal atmospheric pressure. Fluorine has only a single naturally-occurring stable isotope, so isotopologues of UF₆ differ in their molecular weight based solely on the uranium isotope present.^[11]

All the other uranium fluorides are nonvolatile solids that are coordination polymers.

Gaseous diffusion requires about 60 times as much energy as the gas centrifuge process: gaseous diffusion-produced nuclear fuel produces 25 times more energy than is used in the diffusion process, while centrifuge-produced fuel produces 1,500 times more energy than is used in the centrifuge process.

In addition to its use in enrichment, uranium hexafluoride has been used in an advanced reprocessing method (fluoride volatility), which was developed in the Czech Republic. In this process, used oxide nuclear fuel is treated with fluorine gas to form a mixture of fluorides. This mixture is then distilled to separate the different classes of material.

Storage in gas cylinders

DUF₆ cylinders: painted (left) and corroded (right)

About 95% of the depleted uranium produced to date is stored as uranium hexafluoride, DUF₆, in steel cylinders in open air yards close to enrichment plants.^{[citation needed]} Each cylinder contains up to 12.7 tonnes (or 14 US tons) of solid UF₆. In the U.S. alone, 560,000 tonnes of depleted UF₆ had accumulated by 1993.^{[citation needed]} In 2005, 686,500 tonnes in 57,122 storage cylinders were located near Portsmouth, Ohio, Oak Ridge, Tennessee, and Paducah, Kentucky.^[12][13]

The long-term storage of DUF₆ presents environmental, health, and safety risks because of its chemical instability. When UF₆ is exposed to moist air, it reacts with the water in the air to produce UO₂F₂ (uranyl fluoride) and HF (hydrogen fluoride) both of which are highly corrosive and toxic. Storage cylinders must be regularly inspected for signs of corrosion and leaks. The estimated lifetime of the steel cylinders is measured in decades.^[14]

There have been several accidents involving uranium hexafluoride in the United States, including a cylinder-filling accident and material release at the Sequoyah Fuels Corporation in 1986.^[15][16]The U.S. government has been converting DUF₆ to solid uranium oxides for disposal.^[17] Such disposal of the entire DUF₆ inventory could cost anywhere from $15 million to $450 million.^[18]

Ruptured 14-ton UF6 shipping cylinder. 1 fatality, dozens injured. ~29500 lbs of material released. Sequoyah Fuels Corporation 1986.  DUF6 storage yard from afar

References

Literature

• Gmelins Handbuch der anorganischen Chemie, System Nr. 55, Uran, Teil A, p. 121–123.
• Gmelins Handbuch der anorganischen Chemie, System Nr. 55, Uran, Teil C 8, p. 71–163.
• R. DeWitt: Uranium hexafluoride: A survey of the physico-chemical properties, Technical report, GAT-280; Goodyear Atomic Corp., Portsmouth, Ohio; 12. August 1960; doi:10.2172/4025868.
• Ingmar Grenthe, Janusz Drożdżynński, Takeo Fujino, Edgar C. Buck, Thomas E. Albrecht-Schmitt, Stephen F. Wolf: Uranium, in: Lester R. Morss, Norman M. Edelstein, Jean Fuger (Hrsg.): The Chemistry of the Actinide and Transactinide Elements, Springer, Dordrecht 2006; ISBN 1-4020-3555-1, p. 253–698; doi:10.1007/1-4020-3598-5_5 (p. 530–531, 557–564).
• US-Patent 2535572: Preparation of UF₆; 26. December 1950.
• US-Patent 5723837: Uranium Hexafluoride Purification; 3. March 1998.

External links

Wikimedia Commons has media related to [[commons:Lua error in Module:WikidataIB at line 506: attempt to index field 'wikibase' (a nil value).|Lua error in Module:WikidataIB at line 506: attempt to index field 'wikibase' (a nil value).]].

• Simon Cotton (Uppingham School, Rutland, UK): Uranium Hexafluoride.
• Uranium Hexafluoride (UF₆) – Physical and chemical properties of UF₆, and its use in uranium processing – Uranium Hexafluoride and Its Properties
• Import of Western depleted uranium hexafluoride (uranium tails) to Russia
• Uranium Hexafluoride in www.webelements.com