Erbium

iso	NA	half-life	DM	DE (MeV)	DP
¹⁶⁰Er	syn	28.58 h	ε	0.330	¹⁶⁰Ho
¹⁶²Er	0.139%	¹⁶²Er is stable with 94 neutrons
¹⁶⁴Er	1.601%	¹⁶⁴Er is stable with 96 neutrons
¹⁶⁵Er	syn	10.36 h	ε	0.376	¹⁶⁵Ho
¹⁶⁶Er	33.503%	¹⁶⁶Er is stable with 98 neutrons
¹⁶⁷Er	22.869%	¹⁶⁷Er is stable with 99 neutrons
¹⁶⁸Er	26.978%	¹⁶⁸Er is stable with 100 neutrons
¹⁶⁹Er	syn	9.4 d	β⁻	0.351	¹⁶⁹Tm
¹⁷⁰Er	14.910%	¹⁷⁰Er is stable with 102 neutrons
¹⁷¹Er	syn	7.516 h	β⁻	1.490	¹⁷¹Tm
¹⁷²Er	syn	49.3 h	β⁻	0.891	¹⁷²Tm

Erbium (pronounced /ˈɜrbiəm/) is a chemical element in the lanthanide series, with the symbol Er and atomic number 68. A silvery-white solid metal when artificially isolated, natural erbium is always found in chemical combination with other elements on Earth. As such, it is a rare earth element which is associated with several other rare elements in the mineral gadolinite from Ytterby in Sweden.

Erbium's principal uses involve its pink-colored Er³⁺ ions, which have optical fluorescent properties particularly useful in certain laser applications. Erbium-doped glasses or crystals can be used as optical amplification media, where erbium (III) ions are optically pumped at around 980 nm or 1480 nm and then radiate light at 1530 nm in stimulated emission. This process results in an unusually mechanically simple laser optical amplifier for fiberoptically transmitted signals. The 1550 nm wavelength is especially important for optical communications because standard single mode optical fibers have minimal loss at this particular wavelength. In addition to optical fiber lasers, a large variety of medical applications (i.e. dermatology, dentistry) utilize erbium ion's 2940 nm emission (see Er:YAG laser), which is highly absorbed in water (absorption coefficient about 12,000/cm).

1 Characteristics
2 History
3 Occurrence
4 Production
5 Applications
6 Precautions
7 See also
8 References
9 Further reading
10 External links

Characteristics

Physical properties

Erbium(III)chloride in sunlight, showing some pink fluorescence of Er⁺³ from natural ultraviolet.

A trivalent element, pure erbium metal is malleable (or easily shaped), soft yet stable in air, and does not oxidize as quickly as some other rare-earth metals. Its salts are rose-colored, and the element has characteristic sharp absorption spectra bands in visible light, ultraviolet, and near infrared. Otherwise it looks much like the other rare earths. Its sesquioxide is called erbia. Erbium's properties are to a degree dictated by the kind and amount of impurities present. Erbium does not play any known biological role, but is thought to be able to stimulate metabolism.^[1]

Erbium is ferromagnetic below 19 K, antiferromagnetic between 19 and 80 K and paramagnetic above 80 K.^[2]

Erbium can form propeller-shaped atomic clusters Er₃N, where the distance between the erbium atoms is 0.35 nm. Those clusters can be isolated by encapsulating them into fullerene molecules, as confirmed by transmission electron microscopy.^[3]

Chemical properties

Erbium metal tarnishes slowly in air and burns readily to form erbium(III) oxide:

4 Er + 3 O₂ → 2 Er₂O₃

Erbium is quite electropositive and reacts slowly with cold water and quite quickly with hot water to form erbium hydroxide:

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

Erbium metal reacts with all the halogens:

2 Er (s) + 3 F₂ (g) → 2 ErF₃ (s) [pink]

2 Er (s) + 3 Cl₂ (g) → 2 ErCl₃ (s) [violet]

2 Er (s) + 3 Br₂ (g) → 2 ErBr₃ (s) [violet]

2 Er (s) + 3 I₂ (g) → 2 ErI₃ (s) [violet]

Erbium dissolves readily in dilute sulfuric acid to form solutions containing hydrated Er(III) ions, which exist as yellow [Er(OH₂)₉]³⁺ hydration complexes:^[4]

2 Er (s) + 3 H₂SO₄ (aq) → 2 Er³⁺ (aq) + 3 SO2−4 (aq) + 3 H₂ (g)

Isotopes

Naturally occurring erbium is composed of 6 stable isotopes, Er-162, Er-164, Er-166, Er-167, Er-168, and Er-170 with Er-166 being the most abundant (33.503% natural abundance). 29 radioisotopes have been characterized, with the most stable being Er-169 with a half-life of 9.4 days, Er-172 with a half-life of 49.3 hours, Er-160 with a half-life of 28.58 hours, Er-165 with a half-life of 10.36 hours, and Er-171 with a half-life of 7.516 hours. All of the remaining radioactive isotopes have half-lives that are less than 3.5 hours, and the majority of these have half-lives that are less than 4 minutes. This element also has 13 meta states, with the most stable being Er-167m (t_½ 2.269 seconds).^[5]

The isotopes of erbium range in atomic weight from 142.9663 u (Er-143) to 176.9541 u (Er-177). The primary decay mode before the most abundant stable isotope, Er-166, is electron capture, and the primary mode after is beta decay. The primary decay products before Er-166 are element 67 (holmium) isotopes, and the primary products after are element 69 (thulium) isotopes.^[5]

History

Erbium (for Ytterby, a village in Sweden) was discovered by Carl Gustaf Mosander in 1843.^[6] Mosander separated "yttria" from the mineral gadolinite into three fractions which he called yttria, erbia, and terbia. He named the new element after the village of Ytterby where large concentrations of yttria and erbium are located. Erbia and terbia, however, were confused at this time. After 1860, terbia was renamed erbia and after 1877 what had been known as erbia was renamed terbia. Fairly pure Er₂O₃ was independently isolated in 1905 by Georges Urbain and Charles James. Reasonably pure metal wasn't produced until 1934 when Klemm and Bommer reduced the anhydrous chloride with potassium vapor. It was only in the 1990s that the price for Chinese-derived erbium oxide became low enough for erbium to be considered for use as a colorant in art glass.^[7]

Occurrence

Monazite sand

The concentration of erbium in the Earth crust is about 2.8 mg/kg and in the sea water 0.9 ng/L.^[8]. This concentration is enough to make erbium about 45th in elemental abundance in the Earth's crust, more common than more familiar elements such as lead.

Like other rare earths, this element is never found as a free element in nature but is found bound in monazite sand ores. It has historically been very difficult and expensive to separate rare earths from each other in their ores but ion-exchange production techniques^[9] developed in the late 20th century have greatly brought down the cost of production of all rare-earth metals and their chemical compounds.

The principal commercial sources of erbium are from the minerals xenotime and euxenite, and most recently, the ion adsorption clays of southern China; in consequence, China has now become the principal global supplier of this element. In the high-yttrium versions of these ore concentrates, yttrium is about two-thirds of the total by weight, and erbia is about 4-5%. When the concentrate is dissolved in acid, the erbia liberates enough erbium ion to impart a distinct and characteristic pink color to the solution. This color behavior is similar to what Mosander and the other early workers in the lanthanides would have seen in their extracts from the gadolinite minerals of Ytterby.

Production

Crushed minerals are attacked by hydrochloric or sulfuric acid that transforms insoluble rare-earth oxides into soluble chlorides or sulfates. The acidic filtrates are partially neutralized with caustic soda (sodium hydroxide) to pH 3-4. Thorium precipitates out of solution as hydroxide and is removed. After that the solution is treated with ammonium oxalate to convert rare earths into their insoluble oxalates. The oxalates are converted to oxides by annealing. The oxides are dissolved in nitric acid that excludes one of the main components, cerium, whose oxide is insoluble in HNO₃. The solution is treated with magnesium nitrate to produce a crystallized mixture of double salts of rare-earth metals. The salts are separated by ion exchange. In this process, rare-earth ions are sorbed onto suitable ion-exchange resin by exchange with hydrogen, ammonium or cupric ions present in the resin. The rare earth ions are then selectively washed out by suitable complexing agent.^[8] Erbium metal is obtained from its oxide or salts by heating with calcium at 1450 °C under argon atmosphere.^[8]

Applications

Erbium's everyday uses are varied. It is commonly used as a photographic filter, and because of its resilience it is useful as a metallurgical additive. Other uses:

Used in nuclear technology in neutron-absorbing control rods.^[1]^[10]
When added to vanadium as an alloy, erbium lowers hardness and improves workability.^[11]
Erbium oxide has a pink color, and is sometimes used as a colorant for glass, cubic zirconia and porcelain. The glass is then often used in sunglasses and cheap jewelry.^[11]
Erbium-doped optical silica-glass fibers are the active element in erbium-doped fiber amplifiers (EDFAs), which are widely used in optical communications.^[12] The same fibers can be used to create fiber lasers. Co-doping of optical fiber with Er and Yb is used in high-power Er/Yb fiber lasers, which gradually replace CO₂ lasers for metal welding and cutting applications. Erbium can also be used in erbium-doped waveguide amplifiers.^[1]
An erbium-nickel alloy Er₃Ni has an unusually high specific heat capacity at liquid-helium temperatures and is used in cryocoolers; a mixture of 65% Er₃Co and 35% Er_0.9Yb_0.1Ni by volume improves the specific heat capacity even more.^[13]^[14]
A large variety of medical applications (i.e. dermatology, dentistry) utilize erbium ion's 2940 nm emission (see Er:YAG laser), which is highly absorbed in water (absorption coefficient about 12000/cm). Such shallow tissue deposition of laser energy is necessary for laser surgery, and the efficient production of steam for laser enamel ablation in dentistry.

Precautions

As with the other lanthanides, erbium compounds are of low to moderate toxicity, although their toxicity has not been investigated in detail. Metallic erbium in dust form presents a fire and explosion hazard.

References

↑ ^1.0 ^1.1 ^1.2 Emsley, John (2001). "Erbium". Nature's Building Blocks: An A-Z Guide to the Elements. Oxford, England, UK: Oxford University Press. pp. 136–139. ISBN 0-19-850340-7. http://books.google.com/?id=j-Xu07p3cKwC.
↑ M. Jackson (2000). "Magnetism of Rare Earth". The IRM quarterly 10 (3): 1. http://www.irm.umn.edu/quarterly/irmq10-3.pdf.
↑ Yuta Sato; Kazu Suenaga; Shingo Okubo; Toshiya Okazaki; Sumio Iijima (2007). "Structures of D₅_d-C₈₀ and I_h-Er₃N@C₈₀ Fullerenes and Their Rotation Inside Carbon Nanotubes Demonstrated by Aberration-Corrected Electron Microscopy". Nano Letters 7: 3704. doi:10.1021/nl0720152.
↑ "Chemical reactions of Erbium". Webelements. https://www.webelements.com/erbium/chemistry.html. Retrieved 2009-06-06.
↑ ^5.0 ^5.1 Georges, Audi (2003). "The NUBASE Evaluation of Nuclear and Decay Properties". Nuclear Physics A (Atomic Mass Data Center) 729: 3–128. doi:10.1016/j.nuclphysa.2003.11.001.
↑ C. G. Mosander (October 1843) "On the new metals, Lanthanium and Didymium, which are associated with Cerium; and on Erbium and Terbium, new metals associated with Yttria," Philosophical Magazine, series 3, vol. 23, no. 152, pages 241-254. Available on-line at: http://books.google.com/books?ie=ISO-8859-1&output=html&id=uFAwAAAAIAAJ&dq=Mosander+erbium&ots=IX9LKVOIo2&jtp=241 . Note: The first part of this article, which does NOT concern erbium, is a translation of: C. G. Mosander (1842) "Något om Cer och Lanthan" [Some (news) about cerium and lanthanum], Förhandlingar vid de Skandinaviske naturforskarnes tredje möte (Stockholm) [Transactions of the Third Scandinavian Scientist Conference (Stockholm)], vol. 3, pages 387-398. Available on-line (in Swedish): http://books.google.com/books?ie=ISO-8859-1&output=html&id=XK4tAAAAcAAJ&jtp=387 .
↑ Aaron John Ihde (1984). The development of modern chemistry. Courier Dover Publications. pp. 378–379. ISBN 0486642356. http://books.google.com/?id=34KwmkU4LG0C&pg=PA377.
↑ ^8.0 ^8.1 ^8.2 Patnaik, Pradyot (2003). Handbook of Inorganic Chemical Compounds. McGraw-Hill. pp. 293–295. ISBN 0070494398. http://books.google.com/?id=Xqj-TTzkvTEC&pg=PA293. Retrieved 2009-06-06.
↑ Early paper on the use of displacement ion-exchange chromatography to separate rare earths: F.H. Spedding and J.E.Powell (1954) "A practical separation of yttrium group rare earths from gadolinite by ion-exchange," Chemical Engineering Progress, vol. 50, pages 7–15.
↑ edited by Theodore A. Parish, Vyacheslav V. Khromov, Igor Carron. (1999). "Use of UraniumErbium and PlutoniumErbium Fuel in RBMK Reactors". Safety issues associated with Plutonium involvement in the nuclear fuel cycle. CBoston: Kluwer. pp. 121–125. ISBN 9780792355939. http://books.google.com/?id=aamn7uifb3gC.
↑ ^11.0 ^11.1 C. R. Hammond (2000). The Elements, in Handbook of Chemistry and Physics 81st edition. CRC press. ISBN 0849304814.
↑ P.C. Becker, N.A. Olsson, J.R. Simpson ; (1999). Erbium-doped fiber amplifiers fundamentals and technology. San Diego: Academic Press. ISBN 9780120845903. http://books.google.com/?id=uAOq75yt5CcC.
↑ Peter Kittel, ed. Advances in Cryogenic Engineering volume 39a.
↑ Ackermann, Robert A. (1997). Cryogenic Regenerative Heat Exchangers. Springer. p. 58. ISBN 9780306454493. http://books.google.com/?id=nIzviZ_-_NsC.