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{{infobox europium}} | {{infobox europium}} | ||
'''Europium''' is a [[chemical element]]; it has [[Symbol (chemistry)|symbol]] '''Eu''' and [[atomic number]] 63. It is a silvery-white metal of the [[lanthanide]] series that reacts readily with air to form a dark oxide coating. Europium is the most chemically reactive, least dense, and softest of the lanthanides. It is soft enough to be cut with a knife. Europium was discovered in 1896, provisionally designated as Σ; in 1901, it was named after the continent of [[Europe]].<ref name="eu">{{cite web |title=Periodic Table: Europium |publisher=Royal Society of Chemistry |url=https://www.rsc.org/periodic-table/element/63/europium}}</ref> Europium usually assumes the [[oxidation state]] +3, like other members of the lanthanide series, but compounds having oxidation state +2 are also common. All europium compounds with oxidation state +2 are slightly [[redox|reducing]]. Europium has no significant biological role but is relatively non-toxic compared to other [[Heavy metal (chemistry)|heavy metals]]. Most applications of europium exploit the [[phosphorescence]] of europium compounds. Europium is one of the rarest of the [[rare-earth elements]] on Earth.<ref name="Stwertka">Stwertka, Albert. ''A Guide to the Elements'', Oxford University Press, 1996, p. 156. {{ISBN|0-19-508083-1}}</ref> | '''Europium''' is a [[chemical element]]; it has [[Symbol (chemistry)|symbol]] '''Eu''' and [[atomic number]] 63. It is a silvery-white metal of the [[lanthanide]] series that reacts readily with air to form a dark oxide coating. Europium is the most chemically reactive, least dense, and softest of the lanthanides. It is soft enough to be cut with a knife. Europium was discovered in 1896, provisionally designated as Σ; in 1901, it was named after the continent of [[Europe]].<ref name="eu">{{cite web |title=Periodic Table: Europium |publisher=Royal Society of Chemistry |url=https://www.rsc.org/periodic-table/element/63/europium}}</ref> Europium usually assumes the [[oxidation state]] +3, like other members of the lanthanide series, but compounds having oxidation state +2 are also common. All europium compounds with oxidation state +2 are slightly [[redox|reducing]]. Europium has no significant biological role but is relatively non-toxic compared to other [[Heavy metal (chemistry)|heavy metals]]. Most applications of europium exploit the [[phosphorescence]] of europium compounds. Europium is one of the rarest of the [[rare-earth elements]] on Earth.<ref name="Stwertka">Stwertka, Albert. ''A Guide to the Elements'', Oxford University Press, 1996, p. 156. {{ISBN|0-19-508083-1}}</ref> | ||
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Its discoverer, [[Eugène-Anatole Demarçay]], named the element after the continent of [[Europe]].<ref name="eu" /> | Its discoverer, [[Eugène-Anatole Demarçay]], named the element after the continent of [[Europe]].<ref name="eu" /> | ||
==Physical properties== | |||
[[File:Eu-Block.jpg|thumb|left|About 300 g of dendritic sublimated 99.998% pure europium handled in a glove box]] | [[File:Eu-Block.jpg|thumb|left|About 300 g of dendritic sublimated 99.998% pure europium handled in a glove box]] | ||
[[File:Europium on air oxidized.jpg|thumb|left|Oxidized europium, coated with yellow europium(II) carbonate]] | [[File:Europium on air oxidized.jpg|thumb|left|Oxidized europium, coated with yellow europium(II) carbonate]] | ||
Europium is a [[ductile]] metal with a hardness similar to that of [[lead]]. It crystallizes in a [[Cubic crystal system|body-centered cubic]] lattice.<ref name="Holleman" /> | Europium is a [[ductile]] metal with a hardness similar to that of [[lead]]. It crystallizes in a [[Cubic crystal system|body-centered cubic]] lattice.<ref name="Holleman" /> Among the lanthanoids Europium together with ytterbium have the largest volume per mole of metal. Magnetic measurements suggest this is a consequence of these metals being effectively divalent while other lanthanoids are trivalent metals.<ref name="Holleman" />{{rp|1700}} | ||
==Chemical properties== | |||
Europium is the most reactive | The chemistry of europium is broadly [[lanthanide#Chemistry|lanthanoid chemistry]], but | ||
Europium is the most reactive lanthanoid.<ref name="Holleman" />{{rp|1703}} It rapidly oxidizes in air, so that bulk oxidation of a centimeter-sized sample occurs within several days.<ref>{{cite web|url=https://www.elementsales.com/re_exp/index.htm|author=Hamric, David |date=November 2007 |title = Rare-Earth Metal Long Term Air Exposure Test|work=elementsales.com|access-date=2009-08-08}}</ref> Its reactivity with water is comparable to that of [[calcium]], and the reaction is | |||
:{{chem2|2 Eu + 6 H2O → 2 Eu(OH)3 + 3 H2}} | :{{chem2|2 Eu + 6 H2O → 2 Eu(OH)3 + 3 H2}} | ||
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:{{chem2|2 Eu + 3 H2SO4 + 18 H2O → 2 [Eu(H2O)9](3+) + 3 SO4(2−) + 3 H2}} | :{{chem2|2 Eu + 3 H2SO4 + 18 H2O → 2 [Eu(H2O)9](3+) + 3 SO4(2−) + 3 H2}} | ||
===Eu(II) vs. Eu(III)=== | |||
Although usually trivalent, europium readily forms divalent compounds. This behavior is unusual for most lanthanides, which almost exclusively form compounds with an oxidation state of +3. The +2 state has an [[electron configuration]] 4''f''<sup>7</sup> because the half-filled ''f''-shell provides more stability. In terms of size and [[coordination number]], europium(II) and [[barium]](II) are similar. The [[sulfate]]s of both [[Barium sulfate|barium]] and [[Europium(II) sulfate|europium(II)]] are also highly insoluble in water.<ref>{{cite book|doi = 10.1002/9780470132333.ch19|chapter = Europium(II) Salts|title = Inorganic Syntheses|orig-date = 1946|date = 2006|last1 = Cooley|first1 = Robert A.|last2 = Yost|first2 = Don M.|last3 = Stone|first3 = Hosmer W.|isbn = 978-0-470-13233-3|volume = 2|pages = 69–73}}</ref> Divalent europium is a mild reducing agent, oxidizing in air to form Eu(III) compounds. In anaerobic, and particularly geothermal conditions, the divalent form is sufficiently stable that it tends to be incorporated into minerals of calcium and the other alkaline earths. This ion-exchange process is the basis of the "negative [[europium anomaly]]", the low europium content in many lanthanide minerals such as [[monazite]], relative to the [[chondrite|chondritic]] abundance. [[Bastnäsite]] tends to show less of a negative europium anomaly than does monazite, and hence is the major source of europium today. The development of easy methods to separate divalent europium from the other (trivalent) lanthanides made europium accessible even when present in low concentration, as it usually is.<ref>{{Ullmann|volume=31|page=199|last1=McGill|first1=Ian|contribution=Rare Earth Elements|doi=10.1002/14356007.a22_607}}.</ref> | Although usually trivalent, europium readily forms divalent compounds. This behavior is unusual for most lanthanides, which almost exclusively form compounds with an oxidation state of +3. The +2 state has an [[electron configuration]] 4''f''<sup>7</sup> because the half-filled ''f''-shell provides more stability. In terms of size and [[coordination number]], europium(II) and [[barium]](II) are similar. The [[sulfate]]s of both [[Barium sulfate|barium]] and [[Europium(II) sulfate|europium(II)]] are also highly insoluble in water.<ref>{{cite book|doi = 10.1002/9780470132333.ch19|chapter = Europium(II) Salts|title = Inorganic Syntheses|orig-date = 1946|date = 2006|last1 = Cooley|first1 = Robert A.|last2 = Yost|first2 = Don M.|last3 = Stone|first3 = Hosmer W.|isbn = 978-0-470-13233-3|volume = 2|pages = 69–73}}</ref> Divalent europium is a mild reducing agent, oxidizing in air to form Eu(III) compounds. In anaerobic, and particularly geothermal conditions, the divalent form is sufficiently stable that it tends to be incorporated into minerals of calcium and the other alkaline earths. This ion-exchange process is the basis of the "negative [[europium anomaly]]", the low europium content in many lanthanide minerals such as [[monazite]], relative to the [[chondrite|chondritic]] abundance. [[Bastnäsite]] tends to show less of a negative europium anomaly than does monazite, and hence is the major source of europium today. The development of easy methods to separate divalent europium from the other (trivalent) lanthanides made europium accessible even when present in low concentration, as it usually is.<ref>{{Ullmann|volume=31|page=199|last1=McGill|first1=Ian|contribution=Rare Earth Elements|doi=10.1002/14356007.a22_607}}.</ref> | ||
===Isotopes | ====Compounds==== | ||
{{Main article|Europium compounds}} | |||
[[File:Eu-sulfate.jpg|upright=0.9|thumb|right|Europium(III) sulfate, Eu<sub>2</sub>(SO<sub>4</sub>)<sub>3</sub>]] | |||
[[File:Eu-sulfate-luminescence.jpg|upright=0.9|thumb|right|Europium(III) sulfate fluorescing red under ultraviolet light]] | |||
Europium compounds tend to exist in a trivalent oxidation state under most conditions. Commonly these compounds feature Eu(III) bound by 6–9 oxygenic ligands. The Eu(III) sulfates, nitrates and chlorides are soluble in water or polar organic solvents. Lipophilic europium complexes often feature [[Acetylacetone|acetylacetonate]]-like ligands, such as [[Eufod|EuFOD]]. | |||
====Halides==== | |||
Europium metal reacts with all the halogens: | |||
:2 Eu + 3 X<sub>2</sub> → 2 EuX<sub>3</sub> (X = F, Cl, Br, I) | |||
This route gives white europium(III) fluoride (EuF<sub>3</sub>), yellow [[europium(III) chloride]] (EuCl<sub>3</sub>), gray<ref name="Bromide book">{{cite book|last1=Phillips|first1=Sidney L.|last2=Perry|first2=Dale L.|title=Handbook of inorganic compounds|date=1995|publisher=CRC Press|location=Boca Raton|isbn=978-0-8493-8671-8|page=159}}</ref> [[europium(III) bromide]] (EuBr<sub>3</sub>), and colorless europium(III) iodide (EuI<sub>3</sub>). Europium also forms the corresponding dihalides: yellow-green europium(II) fluoride (EuF<sub>2</sub>), colorless [[europium(II) chloride]] (EuCl<sub>2</sub>) (although it has a bright blue fluorescence under UV light),<ref name=HowellEuCl2>{{cite journal |last1=Howell |first1=J.K. |last2=Pytlewski |first2=L.L. |title=Synthesis of divalent europium and ytterbium halides in liquid ammonia |journal=Journal of the Less Common Metals |date=August 1969 |volume=18 |issue=4 |pages=437–439 |doi=10.1016/0022-5088(69)90017-4}}</ref> colorless [[europium(II) bromide]] (EuBr<sub>2</sub>), and green europium(II) iodide (EuI<sub>2</sub>).<ref name="Holleman">Holleman, A. F.; Wiberg, E. "Inorganic Chemistry" Academic Press: San Diego, 2001. {{ISBN|0-12-352651-5}}.</ref> | |||
====Chalcogenides and pnictides==== | |||
Europium forms stable compounds with all of the chalcogens, but the heavier chalcogens (S, Se, and Te) stabilize the lower oxidation state. Three [[oxide]]s are known: europium(II) oxide (EuO), [[europium(III) oxide]] (Eu<sub>2</sub>O<sub>3</sub>), and the [[mixed-valency|mixed-valence]] oxide Eu<sub>3</sub>O<sub>4</sub>, consisting of both Eu(II) and Eu(III). Otherwise, the main chalcogenides are [[europium(II) sulfide]] (EuS), europium(II) selenide (EuSe) and europium(II) telluride (EuTe): all three of these are black solids. Europium(II) sulfide is prepared by sulfiding the oxide at temperatures sufficiently high to decompose the Eu<sub>2</sub>O<sub>3</sub>:<ref>{{cite book|doi = 10.1002/9780470132418.ch15|chapter = Europium (II) Sulfide|title = Inorganic Syntheses|date = 1967|last1 = Archer|first1 = R. D.|last2 = Mitchell|first2 = W. N.|last3 = Mazelsky|first3 = R.|isbn = 978-0-470-13241-8|volume = 10|pages = 77–79}}</ref> | |||
:Eu<sub>2</sub>O<sub>3</sub> + 3 H<sub>2</sub>S → 2 EuS + 3 H<sub>2</sub>O + S | |||
The main [[nitride]] of europium is europium(III) nitride (EuN). | |||
==Isotopes== | |||
{{Main|Isotopes of europium}} | {{Main|Isotopes of europium}} | ||
Naturally occurring europium is composed of two [[isotope]]s, <sup>151</sup>Eu and <sup>153</sup>Eu, which occur in almost equal proportions; <sup>153</sup>Eu is slightly more abundant (52.2% [[natural abundance]]). While <sup>153</sup>Eu is stable, <sup>151</sup>Eu was found to be unstable to [[alpha decay]] with a [[half-life]] of {{val| | Naturally occurring europium is composed of two [[isotope]]s, <sup>151</sup>Eu and <sup>153</sup>Eu, which occur in almost equal proportions; <sup>153</sup>Eu is slightly more abundant (52.2% [[natural abundance]]). While <sup>153</sup>Eu is stable, <sup>151</sup>Eu was found to be unstable to [[alpha decay]] with a [[half-life]] of {{val|4.6|e=18|u=years}},<ref>{{cite journal|first1=N.|last1=Casali |first2=S. S. |last2=Nagorny |first3=F. |last3=Orio |first4=L. |last4=Pattavina |year=2014 |title=Discovery of the <sup>151</sup>Eu α decay |journal=[[Journal of Physics G: Nuclear and Particle Physics]] |volume=41 |number=7 |article-number=075101 |doi=10.1088/0954-3899/41/7/075101 |display-authors=etal|arxiv=1311.2834|bibcode=2014JPhG...41g5101C|s2cid=116920467 }}</ref> giving about one alpha decay per two minutes in every kilogram of natural europium. Besides the natural radioisotope <sup>151</sup>Eu, 39 artificial [[radioisotope]]s have been characterized from <sup>130</sup>Eu to <sup>170</sup>Eu,{{NUBASE2020|ref}}<ref name=Ln922>{{cite journal |last1=Kiss |first1=G. G. |last2=Vitéz-Sveiczer |first2=A. |last3=Saito |first3=Y. |display-authors=et al. |title=Measuring the β-decay properties of neutron-rich exotic Pm, Sm, Eu, and Gd isotopes to constrain the nucleosynthesis yields in the rare-earth region |journal=The Astrophysical Journal |volume=936 |issue=107 |date=2022 |page=107 |doi=10.3847/1538-4357/ac80fc|bibcode=2022ApJ...936..107K |s2cid=252108123 |hdl=2117/375253 |hdl-access=free |doi-access=free }}</ref> the most stable being <sup>150</sup>Eu with a half-life of 36.9 years, <sup>152</sup>Eu with a half-life of 13.516 years, <sup>154</sup>Eu with a half-life of 8.592 years, and <sup>155</sup>Eu with a half-life of 4.742 years. All the others have half-lives shorter than 100 days, with the majority shorter than 3 minutes. | ||
The primary [[decay mode]] for isotopes lighter than <sup>153</sup>Eu is [[electron capture]], and the primary mode for heavier isotopes is [[beta minus decay]] | This element also has 27 [[meta state]]s, with the most stable being <sup>150m</sup>Eu (12.8 hours), <sup>152m1</sup>Eu (9.3116 hours) and <sup>152m5</sup>Eu (96 minutes).{{NUBASE2020|ref}} The primary [[decay mode]] for isotopes lighter than <sup>153</sup>Eu is [[electron capture]] to [[Isotopes of samarium|samarium]] isotopes, and the primary mode for heavier isotopes is [[beta minus decay]] to [[Isotopes of gadolinium|gadolinium]] isotopes. | ||
===Europium as a nuclear fission product=== | |||
{{Medium-lived fission products}} | {{Medium-lived fission products}} | ||
Europium is produced by nuclear fission | Europium is produced by nuclear fission: [[Europium-155|<sup>155</sup>Eu]] (half-life 4.742 years) has a fission yield of 0.033% for [[uranium-235]] with [[thermal neutron]]s.<ref>{{cite journal |last1=Aarkrog |first1=A. |last2=Lippert |first2=J. |title=Europium-155 in Debris from Nuclear Weapons |journal=Science |date=28 July 1967 |volume=157 |issue=3787 |pages=425–427 |doi=10.1126/science.157.3787.425 |pmid=6028023 |bibcode=1967Sci...157..425A }}</ref> The [[fission product yield]]s of europium isotopes are low, as they are near the top of the mass range of [[fission products]]. | ||
[[Europium-155|<sup>155</sup>Eu]] (half-life 4. | |||
The [[fission product yield]]s of europium isotopes are low near the top of the mass range | |||
As with other lanthanides, many isotopes of europium | As with other lanthanides, many isotopes of europium have high [[Neutron cross-section|cross section]]s for [[neutron capture]], often high enough to be [[neutron poison]]s.{{Citation needed|date=September 2025}} | ||
<div style="float:left; margin:0.25em"> | <div style="float:left; margin:0.25em"> | ||
{| class="wikitable" align="right" style="margin:1em" | {| class="wikitable" align="right" style="margin:1em" | ||
|+ Thermal neutron capture cross sections | |+ Thermal neutron capture cross sections{{Citation needed|date=September 2025}} | ||
!Isotope | !Isotope | ||
|<sup>151</sup>Eu||<sup>152</sup>Eu||<sup>153</sup>Eu||<sup>154</sup>Eu||<sup>155</sup>Eu | |<sup>151</sup>Eu||<sup>152</sup>Eu||<sup>153</sup>Eu||<sup>154</sup>Eu||<sup>155</sup>Eu | ||
|- | |- | ||
!Yield | !Yield<br />{{Clarify|date=September 2025 |reason=unit needed}} | ||
|~10||low||1580||>2.5||330 | |~10||low||1580||>2.5||330 | ||
|- | |- | ||
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|} | |} | ||
</div> | </div> | ||
<sup>151</sup>Eu is the [[beta decay]] product of [[samarium-151]], but since this has a long decay half-life and short mean time to neutron absorption, most <sup>151</sup>Sm instead ends up as <sup>152</sup>Sm. | <sup>151</sup>Eu is the [[beta decay]] product of [[samarium-151]] (not included in above yield), but since this has a long decay half-life and short mean time to neutron absorption, most <sup>151</sup>Sm instead ends up as <sup>152</sup>Sm. | ||
<sup>152</sup>Eu (half-life 13. | <sup>152</sup>Eu (half-life 13.517 years) and <sup>154</sup>Eu (half-life 8.592 years) cannot be beta decay products because <sup>152</sup>Sm and <sup>154</sup>Sm are non-radioactive, but <sup>154</sup>Eu is the only long-lived "shielded" [[nuclide]], other than [[Caesium-134|<sup>134</sup>Cs]], to have a fission yield of more than 2.5 [[parts per million]] fissions.<ref>[http://wwwndc.jaea.go.jp/NuC/index.html Tables of Nuclear Data], Japan Atomic Energy Agency {{webarchive |url=https://web.archive.org/web/20150610213313/http://wwwndc.jaea.go.jp/NuC/index.html |date=June 10, 2015 }}</ref> A larger amount of <sup>154</sup>Eu is produced by [[neutron activation]] of a significant portion of the non-radioactive <sup>153</sup>Eu; however, as shown by the cross-sections, much of this is further converted to <sup>155</sup>Eu and <sup>156</sup>Eu, ending up as gadolinium. | ||
==Occurrence== | |||
[[File:Monazit - Mosambik, O-Afrika.jpg|left|thumb|Monazite]] | [[File:Monazit - Mosambik, O-Afrika.jpg|left|thumb|Monazite]] | ||
Europium is not found in nature as a free element. Many minerals contain europium, with the most important sources being [[bastnäsite]], [[monazite]], [[xenotime]] and [[loparite-(Ce)]].<ref name="Kirk">{{cite book |doi=10.1002/0471238961.1201142019010215.a01.pub3 |chapter=Lanthanides |title=Kirk-Othmer Encyclopedia of Chemical Technology |date=2013 |last1=Bünzli |first1=Jean-Claude G. |pages=1–43 |isbn=978-0-471-48494-3 }}</ref> | Europium is not found in nature as a free element. Many minerals contain europium, with the most important sources being [[bastnäsite]], [[monazite]], [[xenotime]] and [[loparite-(Ce)]].<ref name="Kirk">{{cite book |doi=10.1002/0471238961.1201142019010215.a01.pub3 |chapter=Lanthanides |title=Kirk-Othmer Encyclopedia of Chemical Technology |date=2013 |last1=Bünzli |first1=Jean-Claude G. |pages=1–43 |isbn=978-0-471-48494-3 }}</ref> | ||
Depletion or enrichment of europium in minerals relative to other rare-earth elements is known as the [[europium anomaly]].<ref>{{cite book|chapter-url = https://books.google.com/books?id=OmUXW8pqUe8C&pg=PA550|chapter = The Europium anomaly| pages = 550–553|title = Systematics and the properties of the lanthanides|isbn = 978-90-277-1613-2|last = Sinha|first= Shyama P.|author2 = Scientific Affairs Division, North Atlantic Treaty Organization|date = 1983| publisher=Springer }}</ref> Europium is commonly included in trace element studies in [[geochemistry]] and [[petrology]] to understand the processes that form [[igneous rocks]] (rocks that cooled from [[magma]] or [[lava]]). The nature of the europium anomaly found helps reconstruct the relationships within a suite of igneous rocks. The [[Abundance of elements in Earth's crust|median crustal abundance]] of europium is 2 ppm; values of the less abundant elements may vary with location by several orders of magnitude.<ref name=CRC>ABUNDANCE OF ELEMENTS IN THE | Depletion or enrichment of europium in minerals relative to other rare-earth elements is known as the [[europium anomaly]].<ref>{{cite book|chapter-url = https://books.google.com/books?id=OmUXW8pqUe8C&pg=PA550|chapter = The Europium anomaly| pages = 550–553|title = Systematics and the properties of the lanthanides|isbn = 978-90-277-1613-2|last = Sinha|first= Shyama P.|author2 = Scientific Affairs Division, North Atlantic Treaty Organization|date = 1983| publisher=Springer }}</ref> Europium is commonly included in trace element studies in [[geochemistry]] and [[petrology]] to understand the processes that form [[igneous rocks]] (rocks that cooled from [[magma]] or [[lava]]). The nature of the europium anomaly found helps reconstruct the relationships within a suite of igneous rocks. The [[Abundance of elements in Earth's crust|median crustal abundance]] of europium is 2 ppm; values of the less abundant elements may vary with location by several orders of magnitude.<ref name=CRC>ABUNDANCE OF ELEMENTS IN THE EARTH'S CRUST AND IN THE SEA, ''CRC Handbook of Chemistry and Physics,'' 97th edition (2016–2017), p. 14-17</ref> | ||
Divalent europium (Eu<sup>2+</sup>) in small amounts is the activator of the bright blue [[fluorescence]] of some samples of the mineral [[fluorite]] (CaF<sub>2</sub>). The reduction from Eu<sup>3+</sup> to Eu<sup>2+</sup> is induced by irradiation with energetic particles.<ref>{{cite journal|doi = 10.1007/BF00308116|title = Color centers, associated rare-earth ions and the origin of coloration in natural fluorites|date = 1978|last1 = Bill|first1 = H.|last2 = Calas|first2 = G.|journal = Physics and Chemistry of Minerals|volume = 3|issue = 2|pages = 117–131|bibcode=1978PCM.....3..117B|s2cid = 93952343}}</ref> The most outstanding examples of this originated around [[Weardale]] and adjacent parts of northern England; it was the fluorite found here that fluorescence was named after in 1852, although it was not until much later that europium was determined to be the cause.<ref>{{Cite journal|author=Allen, Robert D. |url=http://www.minsocam.org/ammin/AM37/AM37_910.pdf|title=Variations in chemical and physical properties of fluorite|journal=Am. Mineral.|volume=37|pages=910–30|year=1952}}</ref><ref>{{cite journal |last1=Valeur |first1=Bernard |last2=Berberan-Santos |first2=Mário N. |title=A Brief History of Fluorescence and Phosphorescence before the Emergence of Quantum Theory |journal=Journal of Chemical Education |date=June 2011 |volume=88 |issue=6 |pages=731–738 |doi=10.1021/ed100182h |bibcode=2011JChEd..88..731V }}</ref><ref>{{cite journal |last1=Mariano |first1=A.N |last2=King |first2=P.J |title=Europium-activated cathodoluminescence in minerals |journal=Geochimica et Cosmochimica Acta |date=May 1975 |volume=39 |issue=5 |pages=649–660 |doi=10.1016/0016-7037(75)90008-3 |bibcode=1975GeCoA..39..649M }}</ref><ref>{{cite journal |last1=Przibram |first1=K. |title=Fluorescence of Fluorite and the Bivalent Europium Ion |journal=Nature |date=January 1935 |volume=135 |issue=3403 | | Divalent europium (Eu<sup>2+</sup>) in small amounts is the activator of the bright blue [[fluorescence]] of some samples of the mineral [[fluorite]] (CaF<sub>2</sub>). The reduction from Eu<sup>3+</sup> to Eu<sup>2+</sup> is induced by irradiation with energetic particles.<ref>{{cite journal|doi = 10.1007/BF00308116|title = Color centers, associated rare-earth ions and the origin of coloration in natural fluorites|date = 1978|last1 = Bill|first1 = H.|last2 = Calas|first2 = G.|journal = Physics and Chemistry of Minerals|volume = 3|issue = 2|pages = 117–131|bibcode=1978PCM.....3..117B|s2cid = 93952343}}</ref> The most outstanding examples of this originated around [[Weardale]] and adjacent parts of northern England; it was the fluorite found here that fluorescence was named after in 1852, although it was not until much later that europium was determined to be the cause.<ref>{{Cite journal|author=Allen, Robert D. |url=http://www.minsocam.org/ammin/AM37/AM37_910.pdf|title=Variations in chemical and physical properties of fluorite|journal=Am. Mineral.|volume=37|pages=910–30|year=1952}}</ref><ref>{{cite journal |last1=Valeur |first1=Bernard |last2=Berberan-Santos |first2=Mário N. |title=A Brief History of Fluorescence and Phosphorescence before the Emergence of Quantum Theory |journal=Journal of Chemical Education |date=June 2011 |volume=88 |issue=6 |pages=731–738 |doi=10.1021/ed100182h |bibcode=2011JChEd..88..731V }}</ref><ref>{{cite journal |last1=Mariano |first1=A.N |last2=King |first2=P.J |title=Europium-activated cathodoluminescence in minerals |journal=Geochimica et Cosmochimica Acta |date=May 1975 |volume=39 |issue=5 |pages=649–660 |doi=10.1016/0016-7037(75)90008-3 |bibcode=1975GeCoA..39..649M }}</ref><ref>{{cite journal |last1=Przibram |first1=K. |title=Fluorescence of Fluorite and the Bivalent Europium Ion |journal=Nature |date=January 1935 |volume=135 |issue=3403 |page=100 |doi=10.1038/135100a0 |bibcode=1935Natur.135..100P }}</ref> | ||
In [[astrophysics]], the signature of europium in stellar [[spectroscopy|spectra]] can be used to [[Stellar classification|classify stars]] and inform theories of how or where a particular star was born. For instance, astronomers used the relative levels of europium to iron within the star [[LAMOST J112456.61+453531.3]] to propose that the accretion process for star occurred late.<ref>{{cite journal |last1=Xing |first1=Qian-Fan |last2=Zhao |first2=Gang |last3=Aoki |first3=Wako |last4=Honda |first4=Satoshi |last5=Li |first5=Hai-Ning |last6=Ishigaki |first6=Miho N. |last7=Matsuno |first7=Tadafumi |date=29 April 2019 |title=Evidence for the accretion origin of halo stars with an extreme r-process enhancement |journal=[[Nature (journal)|Nature]] |volume= 3|issue= 7|pages= 631–635|doi=10.1038/s41550-019-0764-5 |bibcode=2019NatAs...3..631X |arxiv=1905.04141 |s2cid=150373875 }}</ref> | In [[astrophysics]], the signature of europium in stellar [[spectroscopy|spectra]] can be used to [[Stellar classification|classify stars]] and inform theories of how or where a particular star was born. For instance, astronomers used the relative levels of europium to iron within the star [[LAMOST J112456.61+453531.3]] to propose that the [[Accretion (astrophysics)|accretion]] process for the star occurred late.<ref>{{cite journal |last1=Xing |first1=Qian-Fan |last2=Zhao |first2=Gang |last3=Aoki |first3=Wako |last4=Honda |first4=Satoshi |last5=Li |first5=Hai-Ning |last6=Ishigaki |first6=Miho N. |last7=Matsuno |first7=Tadafumi |date=29 April 2019 |title=Evidence for the accretion origin of halo stars with an extreme r-process enhancement |journal=[[Nature (journal)|Nature]] |volume= 3|issue= 7|pages= 631–635|doi=10.1038/s41550-019-0764-5 |bibcode=2019NatAs...3..631X |arxiv=1905.04141 |s2cid=150373875 }}</ref> | ||
==Production== | ==Production== | ||
Europium is associated with the other rare-earth elements and is, therefore, mined together with them. Separation of the rare-earth elements occurs during later processing. Rare-earth elements are found in the minerals [[bastnäsite]], [[loparite-(Ce)]], [[xenotime]], and [[monazite]] in mineable quantities. Bastnäsite is a group of related | Europium is associated with the other rare-earth elements and is, therefore, mined together with them. Separation of the rare-earth elements occurs during later processing. Rare-earth elements are found in the minerals [[bastnäsite]], [[loparite-(Ce)]], [[xenotime]], and [[monazite]] in mineable quantities. Bastnäsite is a group of related [[fluorocarbonate]]s, Ln(CO<sub>3</sub>)(F,OH). Monazite is a group of related of orthophosphate minerals {{chem|Ln|P|O|4}} (Ln denotes a mixture of all the lanthanides except [[promethium]]), loparite-(Ce) is an oxide, and xenotime is an orthophosphate (Y,Yb,Er,...)PO<sub>4</sub>. Monazite also contains [[thorium]] and [[yttrium]], which complicates handling because thorium and its decay products are radioactive. For the extraction from the ore and the isolation of individual lanthanides, several methods have been developed. The choice of method is based on the concentration and composition of the ore and on the distribution of the individual lanthanides in the resulting concentrate. Roasting the ore, followed by acidic and basic leaching, is used mostly to produce a concentrate of lanthanides. If cerium is the dominant lanthanide, then it is converted from cerium(III) to cerium(IV) and then precipitated. Further separation by [[solvent extraction]]s or [[ion exchange chromatography]] yields a fraction which is enriched in europium. This fraction is reduced with zinc, zinc/amalgam, electrolysis or other methods converting the europium(III) to europium(II). Europium(II) reacts in a way similar to that of [[alkaline earth metal]]s and therefore it can be precipitated as a carbonate or co-precipitated with barium sulfate.<ref name="GuptaL">{{cite journal| pages = 197–248|title =Extractive metallurgy of rare earths|journal = International Materials Reviews|date = 1992|volume = 37|first1 = C. K.|last1 = Gupta|first2 =N.| last2 =Krishnamurthy|issue =1|doi=10.1179/imr.1992.37.1.197|bibcode =1992IMRv...37..197G}}</ref> Europium metal is available through the electrolysis of a mixture of molten EuCl<sub>3</sub> and NaCl (or CaCl<sub>2</sub>) in a graphite cell, which serves as cathode, using graphite as anode. The other product is [[chlorine]] gas.<ref name="Kirk" /><ref name="GuptaL" /><ref>{{cite journal|doi = 10.1016/S0304-386X(01)00156-6|title = Recovery of europium by chemical reduction of a commercial solution of europium and gadolinium chlorides|date = 2001|last1 = Morais|first1 = C.|journal = Hydrometallurgy|volume = 60|issue = 3|pages = 247–253|last2 = Ciminelli|first2 = V. S. T.|author2-link=Virgínia Ciminelli| bibcode=2001HydMe..60..247M }}</ref><ref name="McCoy">{{cite journal|doi =10.1021/ja01300a020|date =1936|last1 =McCoy|first1 =Herbert N.|title = Contribution to the chemistry of europium | journal =Journal of the American Chemical Society|volume =58|issue =9|pages =1577–1580|bibcode =1936JAChS..58.1577M}}</ref><ref>{{cite book|page = 505|url =https://books.google.com/books?id=6aP3te2hGuQC&pg=PA505|title = Handbook of Non-Ferrous Metal Powders: Technologies and Applications|isbn = 978-1-85617-422-0|last1 = Neikov|first1 = Oleg D.|last2 = Naboychenko| first2 = Stanislav|last3 = Gopienko| first3 = Victor G.|last4 = Frishberg|first4 = Irina V.|date = 2009-01-15| publisher=Elsevier }}</ref> | ||
A few large deposits produce or produced a significant amount of the world production. The [[Bayan Obo]] iron ore deposit in [[Inner Mongolia]] contains significant amounts of bastnäsite and monazite and is, with an estimated 36 million tonnes of rare-earth element oxides, the largest known deposit.<ref>{{cite journal | A few large deposits produce or produced a significant amount of the world production. The [[Bayan Obo]] iron ore deposit in [[Inner Mongolia]] contains significant amounts of bastnäsite and monazite and is, with an estimated 36 million tonnes of rare-earth element oxides, the largest known deposit.<ref>{{cite journal | ||
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}}</ref> The mining operations at the Bayan Obo deposit made China the largest supplier of rare-earth elements in the 1990s. Only 0.2% of the rare-earth element content is europium. The second large source for rare-earth elements between 1965 and its closure in the late 1990s was the [[Mountain Pass mine|Mountain Pass rare earth mine]] in California. The bastnäsite mined there is especially rich in the light rare-earth elements (La-Gd, Sc, and Y) and contains only 0.1% of europium. Another large source for rare-earth elements is the loparite found on the [[Kola peninsula]]. It contains besides niobium, tantalum and titanium up to 30% rare-earth elements and is the largest source for these elements in Russia.<ref name="Kirk" /><ref>{{cite journal| doi = 10.1016/S0925-8388(96)02824-1| title = Loparite, a rare-earth ore (Ce, Na, Sr, Ca)(Ti, Nb, Ta, Fe+3)O3| date = 1997| last1 = Hedrick| first1 = J.| last2 = Sinha| first2 = S.| last3 = Kosynkin| first3 = V.| journal = Journal of Alloys and Compounds| volume = 250| issue = 1–2| pages = 467–470| bibcode = 1997JAllC.250..467H}}</ref> | }}</ref> The mining operations at the Bayan Obo deposit made China the largest supplier of rare-earth elements in the 1990s. Only 0.2% of the rare-earth element content is europium. The second large source for rare-earth elements between 1965 and its closure in the late 1990s was the [[Mountain Pass mine|Mountain Pass rare earth mine]] in California. The bastnäsite mined there is especially rich in the light rare-earth elements (La-Gd, Sc, and Y) and contains only 0.1% of europium. Another large source for rare-earth elements is the loparite found on the [[Kola peninsula]]. It contains besides niobium, tantalum and titanium up to 30% rare-earth elements and is the largest source for these elements in Russia.<ref name="Kirk" /><ref>{{cite journal| doi = 10.1016/S0925-8388(96)02824-1| title = Loparite, a rare-earth ore (Ce, Na, Sr, Ca)(Ti, Nb, Ta, Fe+3)O3| date = 1997| last1 = Hedrick| first1 = J.| last2 = Sinha| first2 = S.| last3 = Kosynkin| first3 = V.| journal = Journal of Alloys and Compounds| volume = 250| issue = 1–2| pages = 467–470| bibcode = 1997JAllC.250..467H}}</ref> | ||
==History== | ==History== | ||
Although europium is present in most of the minerals containing the other rare elements, due to the difficulties in separating the elements it was not until the late 1800s that the element was isolated. [[William Crookes]] | Although europium is present in most of the minerals containing the other rare elements, due to the difficulties in separating the elements it was not until the late 1800s that the element was isolated. [[William Crookes]] first noted some anomalous lines in the optical spectrum of samarium-yttrium ores in 1885.<ref name="Sicius-2024">{{Cite book |last=Sicius |first=Hermann |url=https://link.springer.com/10.1007/978-3-662-68921-9 |title=Handbook of the Chemical Elements |date=2024 |publisher=Springer Berlin Heidelberg |isbn=978-3-662-68920-2 |location=Berlin, Heidelberg |language=en |doi=10.1007/978-3-662-68921-9}}</ref>{{rp|936}} In 1892, [[Paul Émile Lecoq de Boisbaudran]] obtained basic fractions from samarium-gadolinium concentrates which had spectral lines not accounted for by samarium or [[gadolinium]]. [[France|French]] [[chemist]] [[Eugène-Anatole Demarçay]] made detailed studies of the spectral lines and suspected these samples of the recently discovered element samarium were contaminated with an unknown element in 1896. Demarçay was able to isolate it in 1901; he then named it ''europium''.<ref>{{cite journal|url = https://gallica.bnf.fr/ark:/12148/bpt6k30888/f1580.image| journal = [[Comptes rendus de l'Académie des sciences|Comptes rendus]]| first = Eugène-Anatole|last = Demarçay|title = Sur un nouvel élément l'europium|volume = 132|pages = 1484–1486|date = 1901}}</ref><ref name="XVI">{{cite journal|doi = 10.1021/ed009p1751|title = The discovery of the elements. XVI. The rare earth elements|date = 1932|last1 = Weeks|first1 = Mary Elvira|author-link1=Mary Elvira Weeks|journal = Journal of Chemical Education|volume = 9|issue = 10|page = 1751|bibcode = 1932JChEd...9.1751W }}</ref><ref name="Marshall">{{cite journal |last1=Marshall |first1=James L. |last2=Marshall |first2=Virginia R. |title=Rediscovery of the Elements: Europium-Eugene Demarçay |journal=The Hexagon |date=2003 |issue=Summer |pages=19–21 |url=https://www.chem.unt.edu/~jimm/REDISCOVERY%207-09-2018/Hexagon%20Articles/demarcay%20and%20europium.pdf |access-date=18 December 2019}}</ref> Crookes confirmed the discovery in 1905 and observed the phosphorescent spectra of the rare elements including those eventually assigned to europium.<ref>{{cite journal|jstor = 92772|pages = 411–414|last1 = Crookes|first1 = W.|author-link=William Crookes|title = On the Phosphorescent Spectra of S δ and Europium|volume = 76|issue = 511|journal = Proceedings of the Royal Society of London|date = 1905|bibcode = 1905RSPSA..76..411C|doi = 10.1098/rspa.1905.0043|doi-access = free}}</ref><ref name="Sicius-2024"/> | ||
==Applications== | ==Applications== | ||
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Relative to most other elements, commercial applications for europium are few and rather specialized. Almost invariably, its phosphorescence is exploited, either in the +2 or +3 oxidation state. | Relative to most other elements, commercial applications for europium are few and rather specialized. Almost invariably, its phosphorescence is exploited, either in the +2 or +3 oxidation state. | ||
It is a [[dopant]] in some types of [[glass]] in [[laser]]s and other optoelectronic devices. Europium oxide (Eu<sub>2</sub>O<sub>3</sub>) is widely used as a red [[phosphor]] in [[cathode-ray tube|television sets]] and [[fluorescent lamps]], and as an activator for [[yttrium]]-based phosphors.<ref name="Caro">{{cite book|chapter-url =https://books.google.com/books?id=P4UCrfp_s0EC&pg=PA323|pages = 323–325|chapter= Rare earths in luminescence|title =Rare earths|isbn =978-84-89784-33-8|last1 =Caro|first1= Paul|date =1998-06-01| publisher=Editorial Complutense }}</ref><ref>{{cite book|chapter-url = https://books.google.com/books?id=aFbgmoyArYoC&pg=PA159| pages = 159–171|chapter= Inorganic Phosphors|title = Chromic phenomena: technological applications of colour chemistry|isbn = 978-0-85404-474-0|author1 = Bamfield, Peter|date = 2001| publisher = Royal Society of Chemistry}}</ref> Color TV screens contain between 0.5 and 1 g of europium oxide.<ref name="Gupta">{{cite book |chapter=Ch. 1.7.10 Phosphors |chapter-url=http://vector.umd.edu/links_files/Extractive%20Metallurgy%20of%20Rare%20Earths%20(Gupta).pdf |title=Extractive metallurgy of rare earths |last1=Gupta |first1=C. K. |last2=Krishnamurthy |first2=N. |publisher=CRC Press |date=2005 |isbn=978-0-415-33340-5 | It is a [[dopant]] in some types of [[glass]] in [[laser]]s and other optoelectronic devices. Europium oxide (Eu<sub>2</sub>O<sub>3</sub>) is widely used as a red [[phosphor]] in [[cathode-ray tube|television sets]] and [[fluorescent lamps]], and as an activator for [[yttrium]]-based phosphors.<ref name="Caro">{{cite book|chapter-url =https://books.google.com/books?id=P4UCrfp_s0EC&pg=PA323|pages = 323–325|chapter= Rare earths in luminescence|title =Rare earths|isbn =978-84-89784-33-8|last1 =Caro|first1= Paul|date =1998-06-01| publisher=Editorial Complutense }}</ref><ref>{{cite book|chapter-url = https://books.google.com/books?id=aFbgmoyArYoC&pg=PA159| pages = 159–171|chapter= Inorganic Phosphors|title = Chromic phenomena: technological applications of colour chemistry|isbn = 978-0-85404-474-0|author1 = Bamfield, Peter|date = 2001| publisher = Royal Society of Chemistry}}</ref> Color TV screens contain between 0.5 and 1 g of europium oxide.<ref name="Gupta">{{cite book |chapter=Ch. 1.7.10 Phosphors |chapter-url=http://vector.umd.edu/links_files/Extractive%20Metallurgy%20of%20Rare%20Earths%20(Gupta).pdf |title=Extractive metallurgy of rare earths |last1=Gupta |first1=C. K. |last2=Krishnamurthy |first2=N. |publisher=CRC Press |date=2005 |isbn=978-0-415-33340-5 |archive-url=https://web.archive.org/web/20120623013009/http://vector.umd.edu/links_files/Extractive%20Metallurgy%20of%20Rare%20Earths%20%28Gupta%29.pdf |archive-date=23 June 2012 }}</ref> Whereas trivalent europium gives red phosphors,<ref>{{Cite journal|last1=Jansen|first1=T.|last2=Jüstel|first2=T.|last3=Kirm|first3=M.|last4=Mägi|first4=H.|last5=Nagirnyi|first5=V.|last6=Tõldsepp|first6=E.|last7=Vielhauer|first7=S.|last8=Khaidukov|first8=N.M.|last9=Makhov|first9=V.N.|title=Site selective, time and temperature dependent spectroscopy of Eu 3+ doped apatites (Mg,Ca,Sr) 2 Y 8 Si 6 O 26|journal=Journal of Luminescence|volume=186|pages=205–211|doi=10.1016/j.jlumin.2017.02.004|bibcode=2017JLum..186..205J|year=2017}}</ref> the luminescence of divalent europium depends strongly on the composition of the host structure. UV to deep red luminescence can be achieved.<ref>{{Cite book|last1=Blasse|first1=G.|last2=Grabmaier|first2=B. C.|title=Luminescent Materials |language=en-gb|doi=10.1007/978-3-642-79017-1|year = 1994|isbn = 978-3-540-58019-5}}</ref><ref>{{Cite journal|last1=Jansen|first1=Thomas|last2=Böhnisch|first2=David|last3=Jüstel|first3=Thomas|s2cid=99095492|date=2016-01-01|title=On the Photoluminescence Linearity of Eu2+ Based LED Phosphors upon High Excitation Density|journal=ECS Journal of Solid State Science and Technology|language=en|volume=5|issue=6|pages=R91–R97|doi=10.1149/2.0101606jss|issn=2162-8769}}</ref> The two classes of europium-based phosphor (red and blue), combined with the yellow/green [[terbium]] phosphors give "white" light, the color temperature of which can be varied by altering the proportion or specific composition of the individual phosphors. This phosphor system is typically encountered in helical fluorescent light bulbs. Combining the same three classes is one way to make trichromatic systems in TV and computer screens,<ref name="Caro" /> but as an additive, it can be particularly effective in improving the intensity of red phosphor.<ref name="Stwertka" /> Europium is also used in the manufacture of fluorescent glass, increasing the general efficiency of fluorescent lamps.<ref name="Stwertka" /> One of the more common persistent after-glow phosphors besides copper-doped zinc sulfide is europium-doped [[strontium aluminate]].<ref>{{cite book| chapter-url = https://books.google.com/books?id=lKCWAaCiaZgC&pg=PA269| chapter = Persistent Afterglow Phosphors| title = Luminescence and Display Phosphors: Phenomena and Applications| isbn = 978-1-60456-018-3| last1 = Lakshmanan| first1 = Arunachalam| date = 2008| publisher = Nova Publishers}}</ref> Europium fluorescence is used to interrogate biomolecular interactions in drug-discovery screens. It is also used in the anti-counterfeiting phosphors in [[euro]] banknotes.<ref>{{cite web| title = Europium and the Euro| url = http://www.smarterscience.com/eurosandeuropium.html| access-date = 2009-06-06| archive-date = 2009-08-04| archive-url = https://web.archive.org/web/20090804012831/http://www.smarterscience.com/eurosandeuropium.html}}</ref><ref>{{cite book|chapter-url = https://books.google.com/books?id=lvQpiVHrb78C&pg=PA77|page = 77|chapter= Euro banknotes|title = Lanthanide and actinide chemistry|isbn = 978-0-470-01006-8|author1 = Cotton, Simon|date = 2006| publisher=Wiley }}</ref> | ||
<!--not an application: Due to its ability to absorb neutrons, it is also being studied for use in nuclear reactors.--> | <!--not an application: Due to its ability to absorb neutrons, it is also being studied for use in nuclear reactors.--> | ||
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There are no clear indications that europium is particularly toxic compared to other [[heavy metals]]. Europium chloride, nitrate and oxide have been tested for toxicity: europium chloride shows an acute intraperitoneal LD<sub>50</sub> toxicity of 550 mg/kg and the acute oral LD<sub>50</sub> toxicity is 5000 mg/kg. Europium nitrate shows a slightly higher intraperitoneal LD<sub>50</sub> toxicity of 320 mg/kg, while the oral toxicity is above 5000 mg/kg.<ref>{{cite journal | doi = 10.1002/jps.2600540435 | title = Pharmacology and toxicology of europium chloride | date = 1965 | last1 = Haley | first1 = Thomas J. | last2 = Komesu | first2 = N. | last3 = Colvin | first3 = G. | last4 = Koste | first4 = L. | last5 = Upham | first5 = H. C. | journal = Journal of Pharmaceutical Sciences | volume = 54 | issue = 4 | pages = 643–5 | pmid = 5842357}}</ref><ref>{{cite journal | doi =10.1016/0041-008X(63)90067-X | pmid =14082480 | title =The acute mammalian toxicity of rare earth nitrates and oxides | date =1963 | last1 =Bruce | first1 =D. | journal =[[Toxicology and Applied Pharmacology]] | volume =5 | issue =6 | pages =750–9 | last2 =Hietbrink | first2 =Bernard E. | last3 =Dubois | first3 =Kenneth P.| bibcode =1963ToxAP...5..750B |id={{DTIC|AD0419188}} }}</ref> The metal dust presents a fire and explosion hazard.<ref>{{cite web |url= | There are no clear indications that europium is particularly toxic compared to other [[heavy metals]]. Europium chloride, nitrate and oxide have been tested for toxicity: europium chloride shows an acute intraperitoneal LD<sub>50</sub> toxicity of 550 mg/kg and the acute oral LD<sub>50</sub> toxicity is 5000 mg/kg. Europium nitrate shows a slightly higher intraperitoneal LD<sub>50</sub> toxicity of 320 mg/kg, while the oral toxicity is above 5000 mg/kg.<ref>{{cite journal | doi = 10.1002/jps.2600540435 | title = Pharmacology and toxicology of europium chloride | date = 1965 | last1 = Haley | first1 = Thomas J. | last2 = Komesu | first2 = N. | last3 = Colvin | first3 = G. | last4 = Koste | first4 = L. | last5 = Upham | first5 = H. C. | journal = Journal of Pharmaceutical Sciences | volume = 54 | issue = 4 | pages = 643–5 | pmid = 5842357 | bibcode = 1965JPhmS..54..643H }}</ref><ref>{{cite journal | doi =10.1016/0041-008X(63)90067-X | pmid =14082480 | title =The acute mammalian toxicity of rare earth nitrates and oxides | date =1963 | last1 =Bruce | first1 =D. | journal =[[Toxicology and Applied Pharmacology]] | volume =5 | issue =6 | pages =750–9 | last2 =Hietbrink | first2 =Bernard E. | last3 =Dubois | first3 =Kenneth P.| bibcode =1963ToxAP...5..750B |id={{DTIC|AD0419188}} }}</ref> The metal dust presents a fire and explosion hazard.<ref>{{cite web |url=https://www.lenntech.com/periodic/elements/eu.htm |title=Europium (Eu) – Chemical properties, Health and Environmental effects |author=Lenntech BV |work=Lenntech Periodic Table |publisher=Lenntech BV |access-date=July 20, 2011}}</ref> | ||
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==References== | ==References== | ||
Latest revision as of 14:14, 30 October 2025
Template:Infobox europium Europium is a chemical element; it has symbol Eu and atomic number 63. It is a silvery-white metal of the lanthanide series that reacts readily with air to form a dark oxide coating. Europium is the most chemically reactive, least dense, and softest of the lanthanides. It is soft enough to be cut with a knife. Europium was discovered in 1896, provisionally designated as Σ; in 1901, it was named after the continent of Europe.[1] Europium usually assumes the oxidation state +3, like other members of the lanthanide series, but compounds having oxidation state +2 are also common. All europium compounds with oxidation state +2 are slightly reducing. Europium has no significant biological role but is relatively non-toxic compared to other heavy metals. Most applications of europium exploit the phosphorescence of europium compounds. Europium is one of the rarest of the rare-earth elements on Earth.[2]
Etymology
Its discoverer, Eugène-Anatole Demarçay, named the element after the continent of Europe.[1]
Physical properties
Europium is a ductile metal with a hardness similar to that of lead. It crystallizes in a body-centered cubic lattice.[3] Among the lanthanoids Europium together with ytterbium have the largest volume per mole of metal. Magnetic measurements suggest this is a consequence of these metals being effectively divalent while other lanthanoids are trivalent metals.[3]Template:Rp
Chemical properties
The chemistry of europium is broadly lanthanoid chemistry, but Europium is the most reactive lanthanoid.[3]Template:Rp It rapidly oxidizes in air, so that bulk oxidation of a centimeter-sized sample occurs within several days.[4] Its reactivity with water is comparable to that of calcium, and the reaction is
Because of the high reactivity, samples of solid europium rarely have the shiny appearance of the fresh metal, even when coated with a protective layer of mineral oil. Europium ignites in air at 150 to 180 °C to form europium(III) oxide:[5]
Europium dissolves readily in dilute sulfuric acid to form pale pink[6] solutions of Template:Chem2:
Eu(II) vs. Eu(III)
Although usually trivalent, europium readily forms divalent compounds. This behavior is unusual for most lanthanides, which almost exclusively form compounds with an oxidation state of +3. The +2 state has an electron configuration 4f7 because the half-filled f-shell provides more stability. In terms of size and coordination number, europium(II) and barium(II) are similar. The sulfates of both barium and europium(II) are also highly insoluble in water.[7] Divalent europium is a mild reducing agent, oxidizing in air to form Eu(III) compounds. In anaerobic, and particularly geothermal conditions, the divalent form is sufficiently stable that it tends to be incorporated into minerals of calcium and the other alkaline earths. This ion-exchange process is the basis of the "negative europium anomaly", the low europium content in many lanthanide minerals such as monazite, relative to the chondritic abundance. Bastnäsite tends to show less of a negative europium anomaly than does monazite, and hence is the major source of europium today. The development of easy methods to separate divalent europium from the other (trivalent) lanthanides made europium accessible even when present in low concentration, as it usually is.[8]
Compounds
Europium compounds tend to exist in a trivalent oxidation state under most conditions. Commonly these compounds feature Eu(III) bound by 6–9 oxygenic ligands. The Eu(III) sulfates, nitrates and chlorides are soluble in water or polar organic solvents. Lipophilic europium complexes often feature acetylacetonate-like ligands, such as EuFOD.
Halides
Europium metal reacts with all the halogens:
- 2 Eu + 3 X2 → 2 EuX3 (X = F, Cl, Br, I)
This route gives white europium(III) fluoride (EuF3), yellow europium(III) chloride (EuCl3), gray[9] europium(III) bromide (EuBr3), and colorless europium(III) iodide (EuI3). Europium also forms the corresponding dihalides: yellow-green europium(II) fluoride (EuF2), colorless europium(II) chloride (EuCl2) (although it has a bright blue fluorescence under UV light),[10] colorless europium(II) bromide (EuBr2), and green europium(II) iodide (EuI2).[3]
Chalcogenides and pnictides
Europium forms stable compounds with all of the chalcogens, but the heavier chalcogens (S, Se, and Te) stabilize the lower oxidation state. Three oxides are known: europium(II) oxide (EuO), europium(III) oxide (Eu2O3), and the mixed-valence oxide Eu3O4, consisting of both Eu(II) and Eu(III). Otherwise, the main chalcogenides are europium(II) sulfide (EuS), europium(II) selenide (EuSe) and europium(II) telluride (EuTe): all three of these are black solids. Europium(II) sulfide is prepared by sulfiding the oxide at temperatures sufficiently high to decompose the Eu2O3:[11]
- Eu2O3 + 3 H2S → 2 EuS + 3 H2O + S
The main nitride of europium is europium(III) nitride (EuN).
Isotopes
Script error: No such module "Labelled list hatnote". Naturally occurring europium is composed of two isotopes, 151Eu and 153Eu, which occur in almost equal proportions; 153Eu is slightly more abundant (52.2% natural abundance). While 153Eu is stable, 151Eu was found to be unstable to alpha decay with a half-life of Template:Val,[12] giving about one alpha decay per two minutes in every kilogram of natural europium. Besides the natural radioisotope 151Eu, 39 artificial radioisotopes have been characterized from 130Eu to 170Eu,Template:NUBASE2020[13] the most stable being 150Eu with a half-life of 36.9 years, 152Eu with a half-life of 13.516 years, 154Eu with a half-life of 8.592 years, and 155Eu with a half-life of 4.742 years. All the others have half-lives shorter than 100 days, with the majority shorter than 3 minutes.
This element also has 27 meta states, with the most stable being 150mEu (12.8 hours), 152m1Eu (9.3116 hours) and 152m5Eu (96 minutes).Template:NUBASE2020 The primary decay mode for isotopes lighter than 153Eu is electron capture to samarium isotopes, and the primary mode for heavier isotopes is beta minus decay to gadolinium isotopes.
Europium as a nuclear fission product
Template:Medium-lived fission products Europium is produced by nuclear fission: 155Eu (half-life 4.742 years) has a fission yield of 0.033% for uranium-235 with thermal neutrons.[14] The fission product yields of europium isotopes are low, as they are near the top of the mass range of fission products.
As with other lanthanides, many isotopes of europium have high cross sections for neutron capture, often high enough to be neutron poisons.Script error: No such module "Unsubst".
| Isotope | 151Eu | 152Eu | 153Eu | 154Eu | 155Eu |
|---|---|---|---|---|---|
| Yield Template:Clarify |
~10 | low | 1580 | >2.5 | 330 |
| Barns | 5900 | 12800 | 312 | 1340 | 3950 |
151Eu is the beta decay product of samarium-151 (not included in above yield), but since this has a long decay half-life and short mean time to neutron absorption, most 151Sm instead ends up as 152Sm.
152Eu (half-life 13.517 years) and 154Eu (half-life 8.592 years) cannot be beta decay products because 152Sm and 154Sm are non-radioactive, but 154Eu is the only long-lived "shielded" nuclide, other than 134Cs, to have a fission yield of more than 2.5 parts per million fissions.[15] A larger amount of 154Eu is produced by neutron activation of a significant portion of the non-radioactive 153Eu; however, as shown by the cross-sections, much of this is further converted to 155Eu and 156Eu, ending up as gadolinium.
Occurrence
Europium is not found in nature as a free element. Many minerals contain europium, with the most important sources being bastnäsite, monazite, xenotime and loparite-(Ce).[16]
Depletion or enrichment of europium in minerals relative to other rare-earth elements is known as the europium anomaly.[17] Europium is commonly included in trace element studies in geochemistry and petrology to understand the processes that form igneous rocks (rocks that cooled from magma or lava). The nature of the europium anomaly found helps reconstruct the relationships within a suite of igneous rocks. The median crustal abundance of europium is 2 ppm; values of the less abundant elements may vary with location by several orders of magnitude.[18]
Divalent europium (Eu2+) in small amounts is the activator of the bright blue fluorescence of some samples of the mineral fluorite (CaF2). The reduction from Eu3+ to Eu2+ is induced by irradiation with energetic particles.[19] The most outstanding examples of this originated around Weardale and adjacent parts of northern England; it was the fluorite found here that fluorescence was named after in 1852, although it was not until much later that europium was determined to be the cause.[20][21][22][23]
In astrophysics, the signature of europium in stellar spectra can be used to classify stars and inform theories of how or where a particular star was born. For instance, astronomers used the relative levels of europium to iron within the star LAMOST J112456.61+453531.3 to propose that the accretion process for the star occurred late.[24]
Production
Europium is associated with the other rare-earth elements and is, therefore, mined together with them. Separation of the rare-earth elements occurs during later processing. Rare-earth elements are found in the minerals bastnäsite, loparite-(Ce), xenotime, and monazite in mineable quantities. Bastnäsite is a group of related fluorocarbonates, Ln(CO3)(F,OH). Monazite is a group of related of orthophosphate minerals Template:Chem (Ln denotes a mixture of all the lanthanides except promethium), loparite-(Ce) is an oxide, and xenotime is an orthophosphate (Y,Yb,Er,...)PO4. Monazite also contains thorium and yttrium, which complicates handling because thorium and its decay products are radioactive. For the extraction from the ore and the isolation of individual lanthanides, several methods have been developed. The choice of method is based on the concentration and composition of the ore and on the distribution of the individual lanthanides in the resulting concentrate. Roasting the ore, followed by acidic and basic leaching, is used mostly to produce a concentrate of lanthanides. If cerium is the dominant lanthanide, then it is converted from cerium(III) to cerium(IV) and then precipitated. Further separation by solvent extractions or ion exchange chromatography yields a fraction which is enriched in europium. This fraction is reduced with zinc, zinc/amalgam, electrolysis or other methods converting the europium(III) to europium(II). Europium(II) reacts in a way similar to that of alkaline earth metals and therefore it can be precipitated as a carbonate or co-precipitated with barium sulfate.[25] Europium metal is available through the electrolysis of a mixture of molten EuCl3 and NaCl (or CaCl2) in a graphite cell, which serves as cathode, using graphite as anode. The other product is chlorine gas.[16][25][26][27][28]
A few large deposits produce or produced a significant amount of the world production. The Bayan Obo iron ore deposit in Inner Mongolia contains significant amounts of bastnäsite and monazite and is, with an estimated 36 million tonnes of rare-earth element oxides, the largest known deposit.[29][30][31] The mining operations at the Bayan Obo deposit made China the largest supplier of rare-earth elements in the 1990s. Only 0.2% of the rare-earth element content is europium. The second large source for rare-earth elements between 1965 and its closure in the late 1990s was the Mountain Pass rare earth mine in California. The bastnäsite mined there is especially rich in the light rare-earth elements (La-Gd, Sc, and Y) and contains only 0.1% of europium. Another large source for rare-earth elements is the loparite found on the Kola peninsula. It contains besides niobium, tantalum and titanium up to 30% rare-earth elements and is the largest source for these elements in Russia.[16][32]
History
Although europium is present in most of the minerals containing the other rare elements, due to the difficulties in separating the elements it was not until the late 1800s that the element was isolated. William Crookes first noted some anomalous lines in the optical spectrum of samarium-yttrium ores in 1885.[33]Template:Rp In 1892, Paul Émile Lecoq de Boisbaudran obtained basic fractions from samarium-gadolinium concentrates which had spectral lines not accounted for by samarium or gadolinium. French chemist Eugène-Anatole Demarçay made detailed studies of the spectral lines and suspected these samples of the recently discovered element samarium were contaminated with an unknown element in 1896. Demarçay was able to isolate it in 1901; he then named it europium.[34][35][36] Crookes confirmed the discovery in 1905 and observed the phosphorescent spectra of the rare elements including those eventually assigned to europium.[37][33]
Applications
Relative to most other elements, commercial applications for europium are few and rather specialized. Almost invariably, its phosphorescence is exploited, either in the +2 or +3 oxidation state.
It is a dopant in some types of glass in lasers and other optoelectronic devices. Europium oxide (Eu2O3) is widely used as a red phosphor in television sets and fluorescent lamps, and as an activator for yttrium-based phosphors.[38][39] Color TV screens contain between 0.5 and 1 g of europium oxide.[40] Whereas trivalent europium gives red phosphors,[41] the luminescence of divalent europium depends strongly on the composition of the host structure. UV to deep red luminescence can be achieved.[42][43] The two classes of europium-based phosphor (red and blue), combined with the yellow/green terbium phosphors give "white" light, the color temperature of which can be varied by altering the proportion or specific composition of the individual phosphors. This phosphor system is typically encountered in helical fluorescent light bulbs. Combining the same three classes is one way to make trichromatic systems in TV and computer screens,[38] but as an additive, it can be particularly effective in improving the intensity of red phosphor.[2] Europium is also used in the manufacture of fluorescent glass, increasing the general efficiency of fluorescent lamps.[2] One of the more common persistent after-glow phosphors besides copper-doped zinc sulfide is europium-doped strontium aluminate.[44] Europium fluorescence is used to interrogate biomolecular interactions in drug-discovery screens. It is also used in the anti-counterfeiting phosphors in euro banknotes.[45][46]
An application that has almost fallen out of use with the introduction of affordable superconducting magnets is the use of europium complexes, such as Eu(fod)3, as shift reagents in NMR spectroscopy. Chiral shift reagents, such as Eu(hfc)3, are still used to determine enantiomeric purity.[47]
Europium compounds are used to label antibodies for sensitive detection of antigens in body fluids, a form of immunoassay. When these europium-labeled antibodies bind to specific antigens, the resulting complex can be detected with laser excited fluorescence.[48]
Precautions
Template:Chembox There are no clear indications that europium is particularly toxic compared to other heavy metals. Europium chloride, nitrate and oxide have been tested for toxicity: europium chloride shows an acute intraperitoneal LD50 toxicity of 550 mg/kg and the acute oral LD50 toxicity is 5000 mg/kg. Europium nitrate shows a slightly higher intraperitoneal LD50 toxicity of 320 mg/kg, while the oral toxicity is above 5000 mg/kg.[49][50] The metal dust presents a fire and explosion hazard.[51]
References
External links
Template:Sister project Template:Sister project
Template:Periodic table (navbox) Template:Europium compounds
- ↑ a b Script error: No such module "citation/CS1".
- ↑ a b c Stwertka, Albert. A Guide to the Elements, Oxford University Press, 1996, p. 156. Template:ISBN
- ↑ a b c d Holleman, A. F.; Wiberg, E. "Inorganic Chemistry" Academic Press: San Diego, 2001. Template:ISBN.
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- ↑ ABUNDANCE OF ELEMENTS IN THE EARTH'S CRUST AND IN THE SEA, CRC Handbook of Chemistry and Physics, 97th edition (2016–2017), p. 14-17
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