Dysprosium

Dysprosium,  66Dy
General properties
Name, symbol dysprosium, Dy
Appearance silvery white
Pronunciation /dɪsˈprziəm/
dis-PROH-zee-əm
Dysprosium in the periodic table


Dy

Cf
terbiumdysprosiumholmium
Atomic number (Z) 66
Group, block group n/a, f-block
Period period 6
Element category   lanthanide
Standard atomic weight (±) (Ar) 162.500(1)[1]
Electron configuration [Xe] 4f10 6s2
per shell
2, 8, 18, 28, 8, 2
Physical properties
Phase solid
Melting point 1680 K (1407 °C, 2565 °F)
Boiling point 2840 K (2562 °C, 4653 °F)
Density near r.t. 8.540 g/cm3
when liquid, at m.p. 8.37 g/cm3
Heat of fusion 11.06 kJ/mol
Heat of vaporization 280 kJ/mol
Molar heat capacity 27.7 J/(mol·K)

vapor pressure

P (Pa) 1 10 100 1 k 10 k 100 k
at T (K) 1378 1523 (1704) (1954) (2304) (2831)
Atomic properties
Oxidation states 4, 3, 2, 1 (a weakly basic oxide)
Electronegativity Pauling scale: 1.22
Ionization energies 1st: 573.0 kJ/mol
2nd: 1130 kJ/mol
3rd: 2200 kJ/mol
Atomic radius empirical: 178 pm
Covalent radius 192±7 pm
Miscellanea
Crystal structure

hexagonal close-packed (hcp)

Hexagonal close packed crystal structure for dysprosium
Speed of sound thin rod 2710 m/s (at 20 °C)
Thermal expansion α, poly: 9.9 µm/(m·K) (r.t.)
Thermal conductivity 10.7 W/(m·K)
Electrical resistivity α, poly: 926 nΩ·m (r.t.)
Magnetic ordering paramagnetic at 300 K
Young's modulus α form: 61.4 GPa
Shear modulus α form: 24.7 GPa
Bulk modulus α form: 40.5 GPa
Poisson ratio α form: 0.247
Vickers hardness 410–550 MPa
Brinell hardness 500–1050 MPa
CAS Number 7429-91-6
History
Discovery Lecoq de Boisbaudran (1886)
Most stable isotopes of dysprosium
iso NA half-life DM DE (MeV) DP
154Dy syn 3.0×106 y α 2.947 150Gd
156Dy 0.06% >1×1018 y (α) 1.7579 152Gd
(β+β+) 2.0108 156Gd
158Dy 0.10% (α) 0.8748 154Gd
+β+) 0.2833 158Gd
160Dy 2.34% (α) 0.4387 156Gd
161Dy 18.91% (α) 0.3443 157Gd
162Dy 25.51% (α) 0.0847 158Gd
163Dy 24.90% (SF) <79.055
164Dy 28.18% (SF) <79.499
Decay modes in parentheses are predicted, but have not yet been observed

Dysprosium is a chemical element with the symbol Dy and atomic number 66. It is a rare earth element with a metallic silver luster. Dysprosium is never found in nature as a free element, though it is found in various minerals, such as xenotime. Naturally occurring dysprosium is composed of seven isotopes, the most abundant of which is 164Dy.

Dysprosium was first identified in 1886 by Paul Émile Lecoq de Boisbaudran, but was not isolated in pure form until the development of ion exchange techniques in the 1950s. Dysprosium is used for its high thermal neutron absorption cross-section in making control rods in nuclear reactors, for its high magnetic susceptibility in data storage applications, and as a component of Terfenol-D. Soluble dysprosium salts are mildly toxic, while the insoluble salts are considered non-toxic.

Characteristics

Physical properties

Dysprosium sample

Dysprosium is a rare earth element that has a metallic, bright silver luster. It is soft enough to be cut with a knife, and can be machined without sparking if overheating is avoided. Dysprosium's physical characteristics can be greatly affected by even small amounts of impurities.[2]

Dysprosium and holmium have the highest magnetic strengths of the elements,[3] especially at low temperatures.[4] Dysprosium has a simple ferromagnetic ordering at temperatures below 85 K (−188.2 °C). Above 85 K (−188.2 °C), it turns into an helical antiferromagnetic state in which all of the atomic moments in a particular basal plane layer are parallel, and oriented at a fixed angle to the moments of adjacent layers. This unusual antiferromagnetism transforms into a disordered (paramagnetic) state at 179 K (−94 °C).[5]

Chemical properties

Dysprosium metal tarnishes slowly in air and burns readily to form dysprosium(III) oxide:

4 Dy + 3 O2 → 2 Dy2O3

Dysprosium is quite electropositive and reacts slowly with cold water (and quite quickly with hot water) to form dysprosium hydroxide:

2 Dy (s) + 6 H2O (l) → 2 Dy(OH)3 (aq) + 3 H2 (g)

Dysprosium metal vigorously reacts with all the halogens at above 200 °C:

2 Dy (s) + 3 F2 (g) → 2 DyF3 (s) [green]
2 Dy (s) + 3 Cl2 (g) → 2 DyCl3 (s) [white]
2 Dy (s) + 3 Br2 (g) → 2 DyBr3 (s) [white]
2 Dy (s) + 3 I2 (g) → 2 DyI3 (s) [green]

Dysprosium dissolves readily in dilute sulfuric acid to form solutions containing the yellow Dy(III) ions, which exist as a [Dy(OH2)9]3+ complex:[6]

2 Dy (s) + 3 H2SO4 (aq) → 2 Dy3+ (aq) + 3 SO2−
4
(aq) + 3 H2 (g)

The resulting compound, dysprosium(III) sulfate, is noticeably paramagnetic.

Compounds

Dysprosium sulfate, Dy2(SO4)3

Dysprosium halides, such as DyF3 and DyBr3, tend to take on a yellow color. Dysprosium oxide, also known as dysprosia, is a white powder that is highly magnetic, more so than iron oxide.[4]

Dysprosium combines with various non-metals at high temperatures to form binary compounds with varying composition and oxidation states +3 and sometimes +2, such as DyN, DyP, DyH2 and DyH3; DyS, DyS2, Dy2S3 and Dy5S7; DyB2, DyB4, DyB6 and DyB12, as well as Dy3C and Dy2C3.[7]

Dysprosium carbonate, Dy2(CO3)3, and dysprosium sulfate, Dy2(SO4)3, result from similar reactions.[8] Most dysprosium compounds are soluble in water, though dysprosium carbonate tetrahydrate (Dy2(CO3)3·4H2O) and dysprosium oxalate decahydrate (Dy2(C2O4)3·10H2O) are both insoluble in water.[9][10] Two of the most abundant dysprosium carbonates, tengerite-(Dy) (Dy2(CO3)3·2–3H2O) and kozoite-(Dy) (DyCO3(OH)) are known to form via a poorly ordered (amorphous) precursor phase with a formula of Dy2(CO3)3·4H2O. This amorphous precursor consists of highly hydrated spherical nanoparticles of 10–20 nm diameter that are exceptionally stable under dry treatment at ambient and high temperatures.[11]

Isotopes

Naturally occurring dysprosium is composed of seven isotopes: 156Dy, 158Dy, 160Dy, 161Dy, 162Dy, 163Dy, and 164Dy. These are all considered stable, although 156Dy decays by alpha decay with a half-life of over 1×1018 years. Of the naturally occurring isotopes, 164Dy is the most abundant at 28%, followed by 162Dy at 26%. The least abundant is 156Dy at 0.06%.[12]

Twenty-nine radioisotopes have also been synthesized, ranging in atomic mass from 138 to 173. The most stable of these is 154Dy, with a half-life of approximately 3×106 years, followed by 159Dym with a half-life of 144.4 days. The least stable is 138Dy, with a half-life of 200 ms. As a general rule, isotopes that are lighter than the stable isotopes tend to decay primarily by β+ decay, while those that are heavier tend to decay by β decay. However, 154Dy decays primarily by alpha decay, and 152Dy and 159Dy decay primarily by electron capture.[12] Dysprosium also has at least 11 metastable isomers, ranging in atomic mass from 140 to 165. The most stable of these is 165mDy, which has a half-life of 1.257 minutes. 149Dy has two metastable isomers, the second of which, 149m2Dy, has a half-life of 28 ns.[12]

History

In 1878, erbium ores were found to contain the oxides of holmium and thulium. French chemist Paul Émile Lecoq de Boisbaudran, while working with holmium oxide, separated dysprosium oxide from it in Paris in 1886.[13] His procedure for isolating the dysprosium involved dissolving dysprosium oxide in acid, then adding ammonia to precipitate the hydroxide. He was only able to isolate dysprosium from its oxide after more than 30 attempts at his procedure. On succeeding, he named the element dysprosium from the Greek dysprositos (δυσπρόσιτος), meaning "hard to get". However, the element was not isolated in relatively pure form until after the development of ion exchange techniques by Frank Spedding at Iowa State University in the early 1950s.[3]

In 1950, Glenn T. Seaborg, Albert Ghiorso, and Stanley G. Thompson bombarded 241Am with helium ions, which produced atoms with an atomic number of 97 and which closely resembled the neighboring lanthanide terbium. Because terbium was named after Ytterby, the city in which it and several other elements were discovered, this new element was named berkelium for the city in which it was synthesized. However, when the research team synthesized element 98, they could not think of a good analogy for dysprosium, and instead named the element californium in honor of the state in which it was synthesized, California. The research team went on to "point out that, in recognition of the fact that dysprosium is named on the basis of a Greek word meaning 'difficult to get at,' that the searchers for another element a century ago found it difficult to get to California".[14]

Occurrence

Xenotime

While Dysprosium is never encountered as a free element, it is found in many minerals, including xenotime, fergusonite, gadolinite, euxenite, polycrase, blomstrandine, monazite and bastnäsite; often with erbium and holmium or other rare earth elements. Currently, most dysprosium is being obtained from the ion-adsorption clay ores of southern China,[15] and future sources will include the Halls Creek region in Western Australia.[16] In the high-yttrium version of these, dysprosium happens to be the most abundant of the heavy lanthanides, comprising up to 7–8% of the concentrate (as compared to about 65% for yttrium).[17][18] The concentration of Dy in the Earth's crust is about 5.2 mg/kg and in sea water 0.9 ng/L.[7]

Production

Dysprosium is obtained primarily from monazite sand, a mixture of various phosphates. The metal is obtained as a by-product in the commercial extraction of yttrium. In isolating dysprosium, most of the unwanted metals can be removed magnetically or by a flotation process. Dysprosium can then be separated from other rare earth metals by an ion exchange displacement process. The resulting dysprosium ions can then react with either fluorine or chlorine to form dysprosium fluoride, DyF3, or dysprosium chloride, DyCl3. These compounds can be reduced using either calcium or lithium metals in the following reactions:[8]

3 Ca + 2 DyF3 → 2 Dy + 3 CaF2
3 Li + DyCl3 → Dy + 3 LiCl

The components are placed in a tantalum crucible and fired in a helium atmosphere. As the reaction progresses, the resulting halide compounds and molten dysprosium separate due to differences in density. When the mixture cools, the dysprosium can be cut away from the impurities.[8]

About 100 tonnes of dysprosium are produced worldwide each year,[19] with 99% of that total produced in China.[20] Dysprosium prices have climbed nearly twentyfold, from $7 per pound in 2003, to $130 a pound in late 2010.[20] According to the United States Department of Energy, the wide range of its current and projected uses, together with the lack of any immediately suitable replacement, makes dysprosium the single most critical element for emerging clean energy technologies - even their most conservative projections predict a shortfall of dysprosium before 2015.[21] As of late 2015, there is a nascent rare earth (including Dysprosium) extraction industry in Australia.[22]

Applications

There are not many applications unique to dysprosium. Theodore Gray wrote in his book The Elements: A Visual Exploration of Every Known Atom in the Universe "Look up dysprosium, and you have to go to the fourth page of results before finding anything that isn't a periodic table website's entry for dysprosium, usually an obligatory 'It's an element, so we have to have a page about it' sort of page."

Dysprosium is used, in conjunction with vanadium and other elements, in making laser materials and commercial lighting. Because of dysprosium's high thermal-neutron absorption cross-section, dysprosium-oxide–nickel cermets are used in neutron-absorbing control rods in nuclear reactors.[3][23] Dysprosium–cadmium chalcogenides are sources of infrared radiation, which is useful for studying chemical reactions.[2] Because dysprosium and its compounds are highly susceptible to magnetization, they are employed in various data-storage applications, such as in hard disks.[24]

Neodymium–iron–boron magnets can have up to 6% of the neodymium substituted by dysprosium[25] to raise the coercivity for demanding applications, such as drive motors for electric vehicles. This substitution would require up to 100 grams of dysprosium per car produced. Based on Toyota's projected 2 million units per year, the use of dysprosium in applications such as this would quickly exhaust its available supply.[26] The dysprosium substitution may also be useful in other applications, because it improves the corrosion resistance of the magnets.[27]

Dysprosium is one of the components of Terfenol-D, along with iron and terbium. Terfenol-D has the highest room-temperature magnetostriction of any known material;[28] which is employed in transducers, wide-band mechanical resonators,[29] and high-precision liquid-fuel injectors.[30]

Dysprosium is used in dosimeters for measuring ionizing radiation. Crystals of calcium sulfate or calcium fluoride are doped with dysprosium. When these crystals are exposed to radiation, the dysprosium atoms become excited and luminescent. The luminescence can be measured to determine the degree of exposure to which the dosimeter has been subjected.[3]

Nanofibers of dysprosium compounds have high strength and a large surface area. Therefore, they can be used to reinforce other materials and act as a catalyst. Fibers of dysprosium oxide fluoride can be produced by heating an aqueous solution of DyBr3 and NaF to 450 °C at 450 bar for 17 hours. This material is remarkably robust, surviving over 100 hours in various aqueous solutions at temperatures exceeding 400 °C without redissolving or aggregating.[31][32][33]

Dysprosium iodide and dysprosium bromide are used in high-intensity metal-halide lamps. These compounds dissociate near the hot center of the lamp, releasing isolated dysprosium atoms. The latter re-emit light in the green and red part of the spectrum, thereby effectively producing bright light.[3][34]

Several paramagnetic crystal salts of dysprosium (Dysprosium Gallium Garnet, DGG; Dysprosium Aluminum Garnet, DAG; Dysprosium Iron Garnet, DyIG) are used in adiabatic demagnetization refrigerators.[35][36]

Precautions

Like many powders, dysprosium powder may present an explosion hazard when mixed with air and when an ignition source is present. Thin foils of the substance can also be ignited by sparks or by static electricity. Dysprosium fires cannot be put out by water. It can react with water to produce flammable hydrogen gas.[37] Dysprosium chloride fires, however, can be extinguished with water,[38] while dysprosium fluoride and dysprosium oxide are non-flammable.[39][40] Dysprosium nitrate, Dy(NO3)3, is a strong oxidizing agent and will readily ignite on contact with organic substances.[4]

Soluble dysprosium salts, such as dysprosium chloride and dysprosium nitrate, are mildly toxic when ingested. The insoluble salts, however, are non-toxic. Based on the toxicity of dysprosium chloride to mice, it is estimated that the ingestion of 500 grams or more could be fatal to a human.[3]

See also

References

  1. Standard Atomic Weights 2013. Commission on Isotopic Abundances and Atomic Weights
  2. 1 2 Lide, David R., ed. (2007–2008). "Dysprosium". CRC Handbook of Chemistry and Physics 4. New York: CRC Press. p. 11. ISBN 978-0-8493-0488-0.
  3. 1 2 3 4 5 6 Emsley, John (2001). Nature's Building Blocks. Oxford: Oxford University Press. pp. 129–132. ISBN 0-19-850341-5.
  4. 1 2 3 Krebs, Robert E. (1998). "Dysprosium". The History and Use of our Earth's Chemical Elements. Greenwood Press. pp. 234–235. ISBN 0-313-30123-9.
  5. Jackson, Mike (2000). "Wherefore Gadolinium? Magnetism of the Rare Earths" (PDF). IRM Quarterly (Institute for Rock Magnetism) 10 (3): 6.
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  11. Vallina, B., Rodriguez-Blanco, J.D., Brown, A.P., Blanco, J.A. and Benning, L.G. (2013) Amorphous dysprosium carbonate: characterization, stability and crystallization pathways. Journal of Nanoparticle Research, 15, 1438. doi: 10.1007/s11051-013-1438-3
  12. 1 2 3 Audi, G.; Bersillon, O.; Blachot, J.; Wapstra, A.H. (2003). "Nubase2003 Evaluation of Nuclear and Decay Properties". Nuclear Physics A (Atomic Mass Data Center) 729: 3–128. Bibcode:2003NuPhA.729....3A. doi:10.1016/j.nuclphysa.2003.11.001.
  13. Paul Émile Lecoq de Boisbaudran (1886). "L'holmine (ou terre X de M Soret) contient au moins deux radicaux métallique (Holminia contains at least two metal)". Comptes Rendus (in French) 143: 1003–1006.
  14. Weeks, M. E. (1968). Discovery of the Elements (7 ed.). Journal of Chemical Education. pp. 848–849. ISBN 0-8486-8579-2. OCLC 23991202.
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  16. Brann, Matt (November 27, 2011). "Halls Creek turning into a hub for rare earths".
  17. Naumov, A. V. (2008). "Review of the World Market of Rare-Earth Metals". Russian Journal of Non-Ferrous Metals 49 (1): 14–22. doi:10.1007/s11981-008-1004-6.
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  20. 1 2 Bradsher, Keith (December 29, 2010). "In China, Illegal Rare Earth Mines Face Crackdown". The New York Times.
  21. New Scientist, 18 June 2011, p. 40
  22. http://www.abc.net.au/news/2015-09-22/rare-earth-miners-face-tough-market/6786970
  23. Amit, Sinha; Sharma, Beant Prakash (2005). "Development of Dysprosium Titanate Based Ceramics". Journal of the American Ceramic Society 88 (4): 1064–1066. doi:10.1111/j.1551-2916.2005.00211.x.
  24. Lagowski, J. J., ed. (2004). Chemistry Foundations and Applications 2. Thomson Gale. pp. 267–268. ISBN 0-02-865724-1.
  25. Shi, Fang, X.; Shi, Y.; Jiles, D.C. (1998). "Modeling of magnetic properties of heat treated Dy-doped NdFeBparticles bonded in isotropic and anisotropic arrangements". IEEE Transactions on Magnetics 34 (4): 1291–1293. Bibcode:1998ITM....34.1291F. doi:10.1109/20.706525.
  26. Campbell, Peter (February 2008). "Supply and Demand, Part 2". Princeton Electro-Technology, Inc. Archived from the original on June 4, 2008. Retrieved 2008-11-09.
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  30. Leavitt, Wendy (February 2000). "Take Terfenol-D and call me". Fleet Owner (RODI Power Systems Inc) 95 (2): 97. Retrieved 2008-11-06.
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  33. M.M. Hoffman, J.S. Young, J.L. Fulton (2000). "Unusual dysprosium ceramic nano-fiber growth in a supercritical aqueous solution". J Mat. Sci. 35 (16): 4177. Bibcode:2000JMatS..35.4177H. doi:10.1023/A:1004875413406.
  34. Theodore Gray (2009). The Elements. Black Dog and Leventhal Publishers. pp. 152–153. ISBN 978-1-57912-814-2.
  35. Steve Milward, Stephen Harrison, Robin Stafford Allen, Ian Hepburn, and Christine Brockley-Blatt (2004). "Design, Manufacture and Test of an Adiabatic Demagnetization Refrigerator Magnet for use in Space" http://www.ucl.ac.uk/mssl/cryogenics/documents/5LH01.pdf
  36. Ian Hepburn (). "Adiabatic Demagnetization Refrigerator: A Practical Point of View" 30. http://www.ucl.ac.uk/mssl/cryogenics/documents/ADR_presentation__Compatibility_Mode_.pdf
  37. Dierks, Steve (January 2003). "Dysprosium". Material Safety Data Sheets. Electronic Space Products International. Retrieved 2008-10-20.
  38. Dierks, Steve (January 1995). "Dysprosium Chloride". Material Safety Data Sheets. Electronic Space Products International. Retrieved 2008-11-07.
  39. Dierks, Steve (December 1995). "Dysprosium Fluoride". Material Safety Data Sheets. Electronic Space Products International. Retrieved 2008-11-07.
  40. Dierks, Steve (November 1988). "Dysprosium Oxide". Material Safety Data Sheets. Electronic Space Products International. Retrieved 2008-11-07.

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