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Information about Uranium Hexafluoride

Uranium hexafluoride
IUPAC nameUranium hexafluoride
Uranium(VI) fluoride
Identifiers
CAS number7783-81-5
Structure
Crystal structureHexagonal close packed (HCP)
Coordination
geometry		Pseudo-octahedral
Molecular shapeOctahedral
Dipole momentzero
Thermochemistry
Std enthalpy of
formation ΔfHo298		-2317 kJ/mol
Standard molar
entropy So298		228 J.K−1.mol−1
Related Compounds
Other anionsUranium(VI) chloride
Other cationsThorium(IV) fluoride
Protactinium(V) fluoride
Neptunium(VI) fluoride
Plutonium(VI) fluoride
Related compoundsUranium trifluoride
Uranium tetrafluoride
Uranium pentafluoride
Except where noted otherwise, data are given for
materials in their standard state
(at 25 C, 100 kPa)


Uranium hexafluoride (UF6), referred to as "hex" in 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 (STP), is highly toxic, reacts violently with water and is corrosive to most metals. It reacts mildly with aluminum, forming a thin surface layer of AlF3 that resists further reaction.

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 finally yields UF6.

Application in the nuclear fuel cycle

Enlarge picture
Phase diagram of UF6.
It is used in both of the main uranium enrichment methods, gaseous diffusion and the gas centrifuge method, because it has a triple point at 147 °F (64 °C, 337 K) and slightly higher than normal atmospheric pressure. Additionally, fluorine has only a single stable naturally occurring isotope, so isotopomers of UF6 differ in their molecular weight based solely on the uranium isotope present.[1]

All the other uranium fluorides are involatile solids which are coordination polymers.

Gaseous diffusion requires ca. 60 times as much energy as the gas centrifuge process; even so, this is just 4% of the energy that can be produced by the resulting enriched uranium.

In addition to its use in enrichment, uranium hexafluoride has been used in an advanced reprocessing method 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 is then distilled to separate the different classes of material.

Storage in gas cylinders

About 95% of the depleted uranium produced to date is stored as uranium hexafluoride, (D)UF6, in steel cylinders in open air yards close to enrichment plants. 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. In 2005, 686,500 tonnes in 57,122 storage cylinders were located near Portsmouth, Ohio, Oak Ridge, Tennessee, and Paducah, Kentucky.[2][3] 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 soluble and toxic. Storage cylinders must be regularly inspected for signs of corrosion and leaks. The estimated life time of the steel cylinders is measured in decades.[4]

There have been several accidents involving uranium hexafluoride in the United States.[5][6] The U.S. government has been converting DUF6 to solid uranium oxides for disposal.[7] Such disposal of the entire DUF6 inventory could cost anywhere from 15 million to 450 million US dollars.[8]

Chemistry

The solid state structure was reported by J.H. Levy, J.C Taylor and A.B Waugh.[9] In this paper neutron diffraction was used to determine the structures of UF6, MoF6 and WF6 at 77K.

This is a simple mononuclear molecule

The crystal structure of uranium hexafluoride


It has been shown that uranium hexafluoride is an oxidant and a lewis acid which is able to bind to fluoride, for instance the reaction of copper fluoride with uranium hexafluoride in acetonitrile is reported to form Cu[UF7]2.5MeCN.[10]

Polymeric uranium(VI) fluorides containing organic cations have been isolated and characterised by X-ray diffraction.[11]

Other uranium fluorides

The pentafluoride of uranium (UF5) and diuranium nonafluoride (U2F9) has been characterised by C.J. Howard, J.C Taylor and A.B. Waugh.[12]

Enlarge picture
It is clear that the solid is a 1D coordination polymer
Enlarge picture
This is U2F9 which is a coordination polymer
Enlarge picture
This is UF4 which is a coordination polymer


The trifluoride of uranium was characterised by J. Laveissiere.[13]

Enlarge picture
This is UF3 which is a coordination polymer


The structure of UOF4 was reported by J.H. Levy, J.C. Taylor, and P.W. Wilson.[14]

See also

External links

References

1. ^ Uranium Enrichment and the Gaseous Diffusion Process. USEC Inc. Retrieved on 2007-09-24.
2. ^ How much depleted uranium hexafluoride is stored in the United States?. Depleted UF6 FAQs. Argonne National Laboratory.
3. ^ [1]
4. ^ What is DUF6? Is it dangerous and what should we do with it?. Institute for Energy and Environmental Research (December 1997).
5. ^ Have there been accidents involving uranium hexafluoride?. Depleted UF6 FAQs. Argonne National Laboratory.
6. ^ Uranium Hexafluoride (UF6) Tailings: Characteritics, Transport and Storage at the Siberian Chemical Combine (Sibkhimkombinat) Tomsk (briefing note). Large and Associates (5 Nov 2005). Retrieved on 2007-09-24.
7. ^ What is going to happen to the uranium hexafluoride stored in the United States?. Depleted UF6 FAQs. Argonne National Laboratory.
8. ^ Are there any currently-operating disposal facilities that can accept all of the depleted uranium oxide that would be generated from conversion of DOE's depleted UF6 inventory?. Depleted UF6 FAQs. Argonne National Laboratory.
9. ^ J.H. Levy, J.C Taylor and A.B Waugh (1983). "Neutron powder structural studies of UF6, MoF6 and WF6 at 77 K". Journal of Fluorine Chemistry 23: 29-36. DOI:10.1016/S0022-1139(00)81276-2. 
10. ^ Berry JA, Poole RT, Prescott A, Sharp DWA, Winfield JM (1976). "The oxidising and fluoride ion acceptor properties of uranium hexafluoride in acetonitrile". J. Chem. Soc. Dalton Trans.: 272. DOI:10.1039/DT9760000272.  x
11. ^ Walker SM, Halasyamani PS, Allen S, O'Hare D (1999). "From Molecules to Frameworks: Variable Dimensionality in the UO2(CH3COO)2·2H2O/HF(aq)/Piperazine System. Syntheses, Structures, and Characterization of Zero-Dimensional (C4N2H12)UO2F4·3H2O, One-Dimensional (C4N2H12)2U2F12·H2O, Two-Dimensional (C4N2H12)2(U2O4F5)4·11H2O, and Three-Dimensional (C4N2H12)U2O4F6". J. Am. Chem. Soc. 121: 10513. DOI:10.1021/ja992145f.  x
12. ^ Howard CJ, Taylor JC, Waugh AB (1982). "Crystallographic parameters in α-UF5 and U2F9 by multiphase refinement of high-resolution neutron powder data". Journal of Solid State Chemistry 45: 396-398. DOI:10.1016/0022-4596(82)90185-2.  x
13. ^ Laveissiere J (1967). "". Bulletin de la Societe Francaise de Mineralogie et de Cristallographie 90: 304-307. 
14. ^ Levy JH, Taylor JC, Wilson PW (1977). "Structure of fluorides .17. NEUTRON-DIFFRACTION STUDY OF ALPHA-URANIUM OXIDE TETRAFLUORIDE". Journal of Inorganic and Nuclear Chemistry 39: 1989-1991. 

Further reading

  • Levy JH (1976). "Structure of fluorides. Part XII. Single-crystal neutron diffraction study of uranium hexafluoride at 293 K". J. Chem. Soc. Dalton Trans.: 219. DOI:10.1039/DT9760000219. x (xstal structure)
  • Olah GH, Welch J (1978). "Synthetic methods and reactions. 46. Oxidation of organic compounds with uranium hexafluoride in haloalkane solutions". J. Am. Chem. Soc. 100: 5396. DOI:10.1021/ja00485a024.  x (selective oxidant of CFCs)
IUPAC nomenclature is a system of naming chemical compounds and of describing the science of chemistry in general. It is developed and kept up to date under the auspices of the International Union of Pure and Applied Chemistry (IUPAC).
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CAS registry numbers are unique numerical identifiers for chemical compounds, polymers, biological sequences, mixtures and alloys. They are also referred to as CAS numbers, CAS RNs or CAS #s.
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crystal structure is a unique arrangement of atoms in a crystal. A crystal structure is composed of a motif, a set of atoms arranged in a particular way, and a lattice. Motifs are located upon the points of a lattice, which is an array of points repeating periodically in three
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hexagonal crystal system is one of the 7 lattice point groups (see Hexagonal_lattice). It has the same symmetry as a right prism with a hexagonal base. There is only one hexagonal Bravais lattice, which has six atoms per unit cell.
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Close-packing of spheres is the arranging of an infinite lattice of spheres so that they take up the greatest possible fraction of an infinite 3-dimensional space. Carl Friedrich Gauss proved that the highest average density that can be achieved by a regular lattice
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The coordination geometry of an atom is the geometrical pattern formed by the coordination of ligands to a metal in a molecule or a coordination complex. The geometrical arrangement of the ligands vary according to the number of ligands bonded to the metal centre, and to the
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An octahedron (plural: octahedra) is a polyhedron with eight faces. A regular octahedron is a Platonic solid composed of eight equilateral triangles, four of which meet at each .

The octahedron's symmetry group is Oh, of order 48.
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The standard enthalpy of formation or "standard heat of formation" of a compound is the change of enthalpy that accompanies the formation of 1 mole of a substance in its standard state from its constituent elements in their standard states (the most stable form of the element at
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In chemistry, the standard molar entropy is the entropy content of one mole of substance, under conditions of standard temperature and pressure (STP).

The standard molar entropy is usually given the symbol So, and the units J mol−1 K
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ion is an atom or molecule which has lost or gained one or more electrons, making it positively or negatively charged. A negatively charged ion, which has more electrons in its electron shells than it has protons in its nuclei, is known as an anion
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ion is an atom or molecule which has lost or gained one or more electrons, making it positively or negatively charged. A negatively charged ion, which has more electrons in its electron shells than it has protons in its nuclei, is known as an anion
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This chemistry related article lacks information on the notability (importance) of the subject matter.
Please help [ improve this article] by providing context for a general audience, especially in the lead section. This article has been tagged since June 2006.
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Uranium tetrafluoride (UF4) is a green crystalline solid compound of uranium with an insignificant vapor pressure and very slight solubility in water. Uranium in its tetravalent (uranous) state is very important in different technological processes.
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Uranium pentafluoride is a coordination polymer which consists of UF5 units linked by bridging fluorides forming linear chains.

The pentafluoride of uranium has been characterised by C.J. Howard, J.C Taylor and A.B.
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standard state of a material is its state at 1 bar (100 kilopascals exactly). This pressure was changed from 1 atm (101.325 kilopascals) by IUPAC in 1990.[1] The standard state of a material can be defined at any given temperature, most commonly 25 degrees Celsius,
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Uranium (IPA: /jʊˈreɪniəm/)is a white/black metallic chemical element in the actinide series of the periodic table that has the symbol U and atomic number 92.
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UO2 pellets in zircaloy cladding.]]

The key components common to most types of nuclear power plants
  • Neutron moderator
  • Coolant
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  • Pressure vessel
  • Emergency Core Cooling Systems (ECCS)
  • Reactor Protective System (RPS)

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In chemistry and other sciences, STP or standard temperature and pressure is a standard set of conditions for experimental measurements, to enable comparisons to be made between sets of data.
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Aluminium (IPA: /ˌæljʊˈmɪniəm/, /ˌæljəˈmɪniəm/) or aluminum (IPA: /əˈluːmɪnəm/
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Yellowcakes (also known as urania) are uranium concentrates obtained from leach solutions. They represent an intermediate step in the processing of uranium ores. Yellowcake concentrates are prepared by various extraction and refining methods, depending on the types of ores.
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The chemical compound nitric acid (HNO3), also known as aqua fortis and spirit of nitre, is an aqueous solution of hydrogen nitrate (anhydrous nitric acid). It is a highly corrosive and toxic acid that can cause severe burns.
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Uranyl nitrate (UO2(NO3)2) is a water soluble yellow uranium salt. Its molecular weight is 394.04 (anhydrous) or 502.13 (hexahydrate) and its CAS number is [ 10102-06-4
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Separation processes

Processes
Acid-base extraction • Chromatography • Crystallization • Dissolved air flotation • Distillation • Drying • Electrochromatography • Filtration • Flocculation • Froth flotation
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Ammonia is a compound with the formula NH3. It is normally encountered as a gas with a characteristic pungent odor. Ammonia contributes significantly to the nutritional needs of the planet as a precursor to foodstuffs and fertilizers.
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Ammonium diuranate or (ADU) ((NH4)2U2O7), is one of the intermediate chemical forms of uranium produced during yellowcake production.
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1, −1
(amphoteric oxide)
Electronegativity 2.20 (Pauling scale) More

Atomic radius 25 pm
Atomic radius (calc.) 53 pm
Covalent radius 37 pm
Van der Waals radius 120 pm
Miscellaneous

Thermal conductivity (300 K) 180.
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Hydrofluoric Acid is a solution of hydrogen fluoride in water. Together with hydrogen fluoride, hydrofluoric acid is a valued source of fluorine, being the precursor to numerous pharmaceuticals, diverse polymers (e.g.
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Uranium tetrafluoride (UF4) is a green crystalline solid compound of uranium with an insignificant vapor pressure and very slight solubility in water. Uranium in its tetravalent (uranous) state is very important in different technological processes.
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100% F is stable with 10 neutrons
References
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