Barium: Difference between revisions

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===Chemical reactivity===
===Chemical reactivity===
Barium is chemically similar to magnesium, calcium, and strontium, but more reactive. Its compounds are almost invariably found in the +2 oxidation state.  As expected for a highly electropositive metal, barium's reaction with [[chalcogen]]s is highly [[exothermic reaction|exothermic]] (release energy). Barium reacts with atmospheric oxygen in air at room temperature. For this reason, metallic barium is often stored under oil or in an inert atmosphere.<ref name="Ullman2005" />{{rp|2}} Reactions with other [[Nonmetal (chemistry)|nonmetal]]s, such as carbon, nitrogen, phosphorus, silicon, and hydrogen, proceed upon heating.<ref name="Ullman2005" />{{rp|2–3}} Reactions with water and alcohols are also exothermic and release hydrogen gas:<ref name="Ullman2005" />{{rp|3}}
Barium is chemically similar to magnesium, calcium, and strontium, but more reactive. Its compounds are almost invariably found in the +2 oxidation state.  As expected for a highly electropositive metal, barium's reaction with [[chalcogen]]s is highly [[exothermic reaction|exothermic]] (release energy). Barium reacts with atmospheric oxygen in air at room temperature. For this reason, metallic barium is often stored under oil or in an inert atmosphere.<ref name="Ullman2005" />{{rp|2}} Reactions with other [[Nonmetal (chemistry)|nonmetal]]s, such as carbon, nitrogen, phosphorus, silicon, and hydrogen, proceed upon heating.<ref name="Ullman2005" />{{rp|2–3}} Reactions with water and alcohols are also exothermic and release hydrogen gas:<ref name="Ullman2005" />{{rp|3}}
: Ba + 2 ROH Ba(OR)<sub>2</sub> + H<sub>2</sub>↑ (R is an alkyl group or a hydrogen atom)
:{{chem2|Ba + 2 ROH -> Ba(OR)2 + H2}}↑ (R is an alkyl group or a hydrogen atom)


Barium reacts with [[ammonia]] to form the electride [Ba(NH<sub>3</sub>)<sub>6</sub>](e<sup>−</sup>)<sub>2</sub>, which near room temperature gives the amide Ba(NH<sub>2</sub>)<sub>2</sub>.<ref>{{Greenwood&Earnshaw2nd|page=113}}</ref>
Barium reacts with [[ammonia]] to form the [[electride]] {{chem2|[Ba(NH3)6](e−)2}}, which near room temperature gives the amide {{chem2|Ba(NH2)2}}.<ref>{{Greenwood&Earnshaw2nd|page=113}}</ref>


The metal is readily attacked by acids. [[Sulfuric acid]] is a notable exception because [[Passivation (chemistry)|passivation]] stops the reaction by forming the insoluble [[barium sulfate]] on the surface.<ref>{{Ullmann |last=Müller |first=Hermann |date= 2000 |title=Sulfuric Acid and Sulfur Trioxide |doi=10.1002/14356007.a25_635 |isbn=9783527306732}}</ref> Barium combines with several other metals, including [[aluminium]], [[zinc]], [[lead]], and [[tin]], forming [[intermetallics|intermetallic phases]] and alloys.<ref>{{cite book|author= Ferro, Riccardo|author2= Saccone, Adriana|name-list-style= amp|page=355|title=Intermetallic Chemistry|publisher=Elsevier|date=2008|isbn=978-0-08-044099-6}}</ref>
The metal is readily attacked by acids. [[Sulfuric acid]] is a notable exception because [[Passivation (chemistry)|passivation]] stops the reaction by forming the insoluble [[barium sulfate]] on the surface.<ref>{{Ullmann |last=Müller |first=Hermann |date= 2000 |title=Sulfuric Acid and Sulfur Trioxide |doi=10.1002/14356007.a25_635 |isbn=9783527306732}}</ref> Barium combines with several other metals, including [[aluminium]], [[zinc]], [[lead]], and [[tin]], forming [[intermetallics|intermetallic phases]] and alloys.<ref>{{cite book|author= Ferro, Riccardo|author2= Saccone, Adriana|name-list-style= amp|page=355|title=Intermetallic Chemistry|publisher=Elsevier|date=2008|isbn=978-0-08-044099-6}}</ref>
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The production of pure oxygen in the [[Brin process]] was a large-scale application of barium peroxide in the 1880s, before it was replaced by electrolysis and [[fractional distillation]] of liquefied air in the early 1900s. In this process barium oxide reacts at {{convert|500|-|600|C|F}} with air to form barium peroxide, which decomposes above {{convert|700|C}} by releasing oxygen:<ref name="O2">{{cite journal|author1-link=William B. Jensen|last1 = Jensen|first1 = William B.|title = The Origin of the Brin Process for the Manufacture of Oxygen|journal = Journal of Chemical Education|volume = 86|pages = 1266|date = 2009|doi = 10.1021/ed086p1266|issue = 11 |bibcode = 2009JChEd..86.1266J}}</ref><ref>{{cite book|url = https://books.google.com/books?id=34KwmkU4LG0C&pg=PA681|page = 681|title = The development of modern chemistry|isbn = 978-0-486-64235-2|author1 = Ihde, Aaron John|date = 1984-04-01| publisher=Dover Publications }}</ref>
The production of pure oxygen in the [[Brin process]] was a large-scale application of barium peroxide in the 1880s, before it was replaced by electrolysis and [[fractional distillation]] of liquefied air in the early 1900s. In this process barium oxide reacts at {{convert|500|-|600|C|F}} with air to form barium peroxide, which decomposes above {{convert|700|C}} by releasing oxygen:<ref name="O2">{{cite journal|author1-link=William B. Jensen|last1 = Jensen|first1 = William B.|title = The Origin of the Brin Process for the Manufacture of Oxygen|journal = Journal of Chemical Education|volume = 86|pages = 1266|date = 2009|doi = 10.1021/ed086p1266|issue = 11 |bibcode = 2009JChEd..86.1266J}}</ref><ref>{{cite book|url = https://books.google.com/books?id=34KwmkU4LG0C&pg=PA681|page = 681|title = The development of modern chemistry|isbn = 978-0-486-64235-2|author1 = Ihde, Aaron John|date = 1984-04-01| publisher=Dover Publications }}</ref>
:2 BaO + O<sub>2</sub> ⇌ 2 BaO<sub>2</sub>
:{{chem2|2 BaO + O2 <-> 2 BaO2}}


Barium sulfate was first applied as a [[radiocontrast]] agent in [[medical imaging|X-ray imaging]] of the digestive system in 1908.<ref>{{cite journal|pmc = 1081520|title = Some Observations on the History of the Use of Barium Salts in Medicine|date = 1974|volume = 18|issue = 1|author=Schott, G. D.|journal=Med. Hist.|pages=9–21|doi = 10.1017/S0025727300019190|pmid = 4618587}}</ref>
Barium sulfate was first applied as a [[radiocontrast]] agent in [[medical imaging|X-ray imaging]] of the digestive system in 1908.<ref>{{cite journal|pmc = 1081520|title = Some Observations on the History of the Use of Barium Salts in Medicine|date = 1974|volume = 18|issue = 1|author=Schott, G. D.|journal=Med. Hist.|pages=9–21|doi = 10.1017/S0025727300019190|pmid = 4618587}}</ref>
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The mined ore is washed, crushed, classified, and separated from quartz. If the quartz penetrates too deeply into the ore, or the iron, zinc, or lead content is abnormally high, then [[froth flotation]]<!--https://books.google.com/books?id=zNicdkuulE4C&pg=PA223--> is used. The product is a 98% pure baryte (by mass); the purity should be no less than 95%, with a minimal content of iron and [[silicon dioxide]].<ref name="Ullman2005" />{{rp|7}} It is then reduced by carbon to [[barium sulfide]]:<ref name="Ullman2005" />{{rp|6}}
The mined ore is washed, crushed, classified, and separated from quartz. If the quartz penetrates too deeply into the ore, or the iron, zinc, or lead content is abnormally high, then [[froth flotation]]<!--https://books.google.com/books?id=zNicdkuulE4C&pg=PA223--> is used. The product is a 98% pure baryte (by mass); the purity should be no less than 95%, with a minimal content of iron and [[silicon dioxide]].<ref name="Ullman2005" />{{rp|7}} It is then reduced by carbon to [[barium sulfide]]:<ref name="Ullman2005" />{{rp|6}}
:BaSO<sub>4</sub> + 2 C BaS + 2 CO<sub>2</sub>
:{{chem2|BaSO4 + 2 C -> BaS + 2 CO2}}


The water-soluble barium sulfide is the starting point for other compounds: treating BaS with oxygen produces the sulfate, with nitric acid the nitrate, with aqueous carbon dioxide the carbonate, and so on.<ref name="Ullman2005" />{{rp|6}} The nitrate can be thermally decomposed to yield the oxide.<ref name="Ullman2005" />{{rp|6}} Barium metal is produced by reduction with [[aluminium]] at {{convert|1100|C}}. The [[intermetallic compound]] BaAl<sub>4</sub> is produced first:<ref name="Ullman2005" />{{rp|3}}
The water-soluble barium sulfide is the starting point for other compounds: treating BaS with oxygen produces the sulfate, with nitric acid the nitrate, with aqueous carbon dioxide the carbonate, and so on.<ref name="Ullman2005" />{{rp|6}} The nitrate can be thermally decomposed to yield the oxide.<ref name="Ullman2005" />{{rp|6}} Barium metal is produced by reduction with [[aluminium]] at {{convert|1100|C}}. The [[intermetallic compound]] BaAl<sub>4</sub> is produced first:<ref name="Ullman2005" />{{rp|3}}
:3 BaO + 14 Al 3 BaAl<sub>4</sub> + Al<sub>2</sub>O<sub>3</sub>
:{{chem2|3 BaO + 14 Al -> 3 BaAl4 + Al2O3}}


BaAl<sub>4</sub> is an intermediate reacted with barium oxide to produce the metal. Note that not all barium is reduced.<ref name="Ullman2005" />{{rp|3}}
{{chem2|BaAl4}} is an intermediate reacted with barium oxide to produce the metal. Note that not all barium is reduced.<ref name="Ullman2005" />{{rp|3}}
:8 BaO + BaAl<sub>4</sub> → Ba↓ + 7 BaAl<sub>2</sub>O<sub>4</sub>
:{{chem2|8 BaO + BaAl4 -> Ba↓ + 7 BaAl2O4}}


The remaining barium oxide reacts with the formed aluminium oxide:<ref name="Ullman2005" />{{rp|3}}
The remaining barium oxide reacts with the formed aluminium oxide:<ref name="Ullman2005" />{{rp|3}}
:BaO + Al<sub>2</sub>O<sub>3</sub> → BaAl<sub>2</sub>O<sub>4</sub>
:{{chem2|BaO + Al2O3 -> BaAl2O4}}


and the overall reaction is<ref name="Ullman2005" />{{rp|3}}
and the overall reaction is<ref name="Ullman2005" />{{rp|3}}
:4 BaO + 2 Al → 3 Ba↓ + BaAl<sub>2</sub>O<sub>4</sub>
:{{chem2|4 BaO + 2 Al → 3 Ba↓ + BaAl2O4}}


Barium vapor is condensed and packed into molds in an atmosphere of argon.<ref name="Ullman2005" />{{rp|3}} This method is used commercially, yielding ultrapure barium.<ref name="Ullman2005" />{{rp|3}} Commonly sold barium is about 99% pure, with main impurities being strontium and calcium (up to 0.8% and 0.25%) and other contaminants contributing less than 0.1%.<ref name="Ullman2005" />{{rp|4}}
Barium vapor is condensed and packed into molds in an atmosphere of argon.<ref name="Ullman2005" />{{rp|3}} This method is used commercially, yielding ultrapure barium.<ref name="Ullman2005" />{{rp|3}} Commonly sold barium is about 99% pure, with main impurities being strontium and calcium (up to 0.8% and 0.25%) and other contaminants contributing less than 0.1%.<ref name="Ullman2005" />{{rp|4}}
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===Barium in seawater===
===Barium in seawater===
Barium exists in seawater as the Ba<sup>2+</sup> ion with an average oceanic concentration of 109 nmol/kg.<ref name="www.mbari.org">{{Cite web|title=Barium|url=https://www.mbari.org/wp-content/static/chemsensor/ba/barium.html|access-date=2020-11-24|website=www.mbari.org}}</ref> Barium also exists in the ocean as BaSO<sub>4</sub>, or barite.<ref name="Griffith-2012">{{Cite journal|last1=Griffith|first1=Elizabeth M.|last2=Paytan|first2=Adina|date=2012|title=Barite in the ocean – occurrence, geochemistry and palaeoceanographic applications|url=|journal=Sedimentology|language=en|volume=59|issue=6|pages=1817–1835|doi=10.1111/j.1365-3091.2012.01327.x|bibcode=2012Sedim..59.1817G| s2cid=28056031 |issn=1365-3091}}</ref>  Barium has a nutrient-like profile<ref>{{Cite web|title=Graph|url=https://www.mbari.org/wp-content/static/chemsensor/ba/bagraph.html|access-date=2020-11-24|website=www.mbari.org}}</ref> with a residence time of 10,000 years.<ref name="www.mbari.org" />
Barium exists in seawater as the Ba<sup>2+</sup> ion with an average oceanic concentration of 109 nmol/kg.<ref name="www.mbari.org">{{Cite web|title=Barium|url=https://www.mbari.org/wp-content/static/chemsensor/ba/barium.html|access-date=2020-11-24|website=www.mbari.org}}</ref> Barium also exists in the ocean as BaSO<sub>4</sub>, or barite.<ref name="Griffith-2012">{{Cite journal|last1=Griffith|first1=Elizabeth M.|last2=Paytan|first2=Adina|date=2012|title=Barite in the ocean – occurrence, geochemistry and palaeoceanographic applications|url=|journal=Sedimentology|language=en|volume=59|issue=6|pages=1817–1835|doi=10.1111/j.1365-3091.2012.01327.x|bibcode=2012Sedim..59.1817G| s2cid=28056031 |issn=1365-3091}}</ref>  Barium has a nutrient-like profile<ref>{{Cite web|title=Graph|url=https://www.mbari.org/wp-content/static/chemsensor/ba/bagraph.html|access-date=2020-11-24|website=www.mbari.org}}</ref> with a residence time of 10,000 years.<ref name="www.mbari.org" />


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==Applications==
==Applications==
===Metal and alloys===
===Metal and alloys===
Barium, as a metal or when alloyed with aluminium, is used to remove unwanted gases ([[getter]]ing) from vacuum tubes, such as TV picture tubes.<ref name="Ullman2005" />{{rp|4}} Barium is suitable for this purpose because of its low [[vapor pressure]] and reactivity towards oxygen, nitrogen, carbon dioxide, and water; it can even partly remove noble gases by dissolving them in the crystal lattice. This application is gradually disappearing due to the rising popularity of the tubeless LCD, LED, and plasma sets.<ref name="Ullman2005" />{{rp|4}}
Barium, as a metal or when alloyed with aluminium, is used to remove unwanted gases ([[getter]]ing) from vacuum tubes, such as TV picture tubes.<ref name="Ullman2005" />{{rp|4}} Barium is suitable for this purpose because of its low [[vapor pressure]] and reactivity towards oxygen, nitrogen, carbon dioxide, and water; it can even partly remove noble gases by dissolving them in the crystal lattice. This application is gradually disappearing due to the rising popularity of the tubeless LCD, LED, and plasma sets.<ref name="Ullman2005" />{{rp|4}}
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===Other barium compounds===
===Other barium compounds===
[[File:2006 Fireworks 1.JPG|thumb|Green barium fireworks]]
[[File:2006 Fireworks 1.JPG|thumb|Green barium fireworks]]
Other compounds of barium find only niche applications, limited by the toxicity of Ba<sup>2+</sup> ions (see {{Section_link||Toxicity}}), which is not a problem for the insoluble BaSO<sub>4</sub>.
Other compounds of barium find only niche applications, limited by the toxicity of {{chem2|Ba(2+)}} ions (see {{Section_link||Toxicity}}), which is not a problem for the insoluble {{chem2|BaSO4}}.
* [[Barium oxide]] coating on the [[electrode]]s of [[fluorescent lamp]]s facilitates the release of [[electron]]s.
* [[Barium oxide]] coating on the [[electrode]]s of [[fluorescent lamp]]s facilitates the release of [[electron]]s.
* By its great atomic density, [[barium carbonate]] increases the [[refractive index]] and luster of glass<ref name="Lide2004" />{{rp|4–5}} and reduces leaks of X-rays from [[cathode-ray tube|CRT]] screens.<ref name="Ullman2005" />{{rp|12–13}}
* By its great atomic density, [[barium carbonate]] increases the [[refractive index]] and luster of glass<ref name="Lide2004" />{{rp|4–5}} and reduces leaks of X-rays from [[cathode-ray tube|CRT]] screens.<ref name="Ullman2005" />{{rp|12–13}}
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* [[Barium fluoride]] is used for optics in infrared applications because of its wide transparency range of 0.15–12&nbsp;micrometers.<ref>{{cite web |url=http://www.crystran.co.uk/barium-fluoride-baf2.htm |title=Crystran Ltd. Optical Component Materials |work=crystran.co.uk |access-date=2010-12-29 |archive-date=2010-06-11 |archive-url=https://web.archive.org/web/20100611112530/http://www.crystran.co.uk/barium-fluoride-baf2.htm |url-status=dead }}</ref>
* [[Barium fluoride]] is used for optics in infrared applications because of its wide transparency range of 0.15–12&nbsp;micrometers.<ref>{{cite web |url=http://www.crystran.co.uk/barium-fluoride-baf2.htm |title=Crystran Ltd. Optical Component Materials |work=crystran.co.uk |access-date=2010-12-29 |archive-date=2010-06-11 |archive-url=https://web.archive.org/web/20100611112530/http://www.crystran.co.uk/barium-fluoride-baf2.htm |url-status=dead }}</ref>
* [[Yttrium barium copper oxide|YBCO]] was the first [[High-temperature superconductivity|high-temperature superconductor]] cooled by liquid nitrogen, with a transition temperature of {{convert|93|K|C F}} greater than the boiling point of nitrogen ({{convert|77|K|C F|disp=or}}).<ref>{{cite journal|title = Superconductivity at 93 K in a New Mixed-Phase Y-Ba-Cu-O Compound System at Ambient Pressure|journal = Physical Review Letters|date = 1987|volume = 58|pages = 908–910|doi = 10.1103/PhysRevLett.58.908|pmid = 10035069|issue = 9|bibcode=1987PhRvL..58..908W|last1 = Wu|first1 = M.|last2 = Ashburn|first2 = J.|last3 = Torng|first3 = C.|last4 = Hor|first4 = P.|last5 = Meng|first5 = R.|last6 = Gao|first6 = L.|last7 = Huang|first7 = Z.|last8 = Wang|first8 = Y.|last9 = Chu|first9 = C.|doi-access = free}}</ref>
* [[Yttrium barium copper oxide|YBCO]] was the first [[High-temperature superconductivity|high-temperature superconductor]] cooled by liquid nitrogen, with a transition temperature of {{convert|93|K|C F}} greater than the boiling point of nitrogen ({{convert|77|K|C F|disp=or}}).<ref>{{cite journal|title = Superconductivity at 93 K in a New Mixed-Phase Y-Ba-Cu-O Compound System at Ambient Pressure|journal = Physical Review Letters|date = 1987|volume = 58|pages = 908–910|doi = 10.1103/PhysRevLett.58.908|pmid = 10035069|issue = 9|bibcode=1987PhRvL..58..908W|last1 = Wu|first1 = M.|last2 = Ashburn|first2 = J.|last3 = Torng|first3 = C.|last4 = Hor|first4 = P.|last5 = Meng|first5 = R.|last6 = Gao|first6 = L.|last7 = Huang|first7 = Z.|last8 = Wang|first8 = Y.|last9 = Chu|first9 = C.|doi-access = free}}</ref>
* [[Ferrite (magnet)|Ferrite]], a type of [[sintering|sintered]] ceramic composed of iron oxide (Fe<sub>2</sub>O<sub>3</sub>) and barium oxide (BaO), is both [[electrical conductivity|electrically nonconductive]] and [[ferrimagnetic]], and can be temporarily or permanently magnetized.
* [[Ferrite (magnet)|Ferrite]], a type of [[sintering|sintered]] ceramic composed of iron oxide ({{chem2|Fe2O3}}) and barium oxide (BaO), is both [[electrical conductivity|electrically nonconductive]] and [[ferrimagnetic]], and can be temporarily or permanently magnetized.
<!-- *The ratio of barium (biogenic barium) to aluminium within marine cores is used as a proxy for surface ocean export production in the past.<ref>{{cite journal|doi = 10.1016/S0025-3227(04)00004-0|title = Biogenic barium and the detrital Ba/Al ratio: a comparison of their direct and indirect determination|year = 2004|last1 = Reitz|first1 = A.|journal = Marine Geology|volume = 204|issue = 3–4|pages = 289–300|last2 = Pfeifer|first2 = K.|last3 = De Lange|first3 = G. J.|last4 = Klump|first4 = J.}}</ref>-->
<!-- *The ratio of barium (biogenic barium) to aluminium within marine cores is used as a proxy for surface ocean export production in the past.<ref>{{cite journal|doi = 10.1016/S0025-3227(04)00004-0|title = Biogenic barium and the detrital Ba/Al ratio: a comparison of their direct and indirect determination|year = 2004|last1 = Reitz|first1 = A.|journal = Marine Geology|volume = 204|issue = 3–4|pages = 289–300|last2 = Pfeifer|first2 = K.|last3 = De Lange|first3 = G. J.|last4 = Klump|first4 = J.}}</ref>-->


===Palaeoceanography===
===Palaeoceanography===
The lateral mixing of barium is caused by water mass mixing and ocean circulation.<ref name="Pyle-2018">{{Cite journal|last1=Pyle|first1=Kimberley M.|last2=Hendry|first2=Katharine R.|last3=Sherrell|first3=Robert M.|last4=Legge|first4=Oliver|last5=Hind|first5=Andrew J.|last6=Bakker|first6=Dorothee|last7=Venables|first7=Hugh|last8=Meredith|first8=Michael P.|date=2018-08-20|title=Oceanic fronts control the distribution of dissolved barium in the Southern Ocean|url=https://ueaeprints.uea.ac.uk/id/eprint/67533/1/Accepted_manuscript.pdf|journal=Marine Chemistry|language=en|volume=204|pages=95–106|doi=10.1016/j.marchem.2018.07.002|bibcode=2018MarCh.204...95P |s2cid=104170533|issn=0304-4203|hdl=1983/ff280483-67cd-46a3-9548-1a782098ea27|hdl-access=free}}</ref> Global ocean circulation reveals a strong correlation between dissolved barium and silicic acid.<ref name="Pyle-2018" /> The large-scale ocean circulation combined with remineralization of barium show a similar correlation between dissolved barium and ocean alkalinity.<ref name="Pyle-2018" />
The lateral mixing of barium is caused by water mass mixing and ocean circulation.<ref name="Pyle-2018">{{Cite journal|last1=Pyle|first1=Kimberley M.|last2=Hendry|first2=Katharine R.|last3=Sherrell|first3=Robert M.|last4=Legge|first4=Oliver|last5=Hind|first5=Andrew J.|last6=Bakker|first6=Dorothee|last7=Venables|first7=Hugh|last8=Meredith|first8=Michael P.|date=2018-08-20|title=Oceanic fronts control the distribution of dissolved barium in the Southern Ocean|url=https://ueaeprints.uea.ac.uk/id/eprint/67533/1/Accepted_manuscript.pdf|journal=Marine Chemistry|language=en|volume=204|pages=95–106|doi=10.1016/j.marchem.2018.07.002|bibcode=2018MarCh.204...95P |s2cid=104170533|issn=0304-4203|hdl=1983/ff280483-67cd-46a3-9548-1a782098ea27|hdl-access=free}}</ref> Global ocean circulation reveals a strong correlation between dissolved barium and silicic acid.<ref name="Pyle-2018" /> The large-scale ocean circulation combined with remineralization of barium show a similar correlation between dissolved barium and ocean alkalinity.<ref name="Pyle-2018" />


Dissolved barium's correlation with silicic acid can be seen both vertically and spatially.<ref name="Bates-2017">{{Cite journal|last1=Bates|first1=Stephanie L.|last2=Hendry|first2=Katharine R.|last3=Pryer|first3=Helena V.|last4=Kinsley|first4=Christopher W.|last5=Pyle|first5=Kimberley M.|last6=Woodward|first6=E. Malcolm S.|last7=Horner|first7=Tristan J.|date=2017-05-01|title=Barium isotopes reveal role of ocean circulation on barium cycling in the Atlantic|url=https://research-information.bris.ac.uk/ws/files/100680705/Bates_Ba_isotopes_FINAL.pdf|journal=Geochimica et Cosmochimica Acta|language=en|volume=204|pages=286–299|doi=10.1016/j.gca.2017.01.043|bibcode=2017GeCoA.204..286B|issn=0016-7037|hdl=1912/8676|s2cid=55559902 |hdl-access=free}}</ref> Particulate barium shows a strong correlation with [[Particulate organic matter|particulate organic carbon]] or POC.<ref name="Bates-2017" /> Barium is becoming more popular as a base for palaeoceanographic proxies.<ref name="Bates-2017" /> With both dissolved and particulate barium's links with silicic acid and POC, it can be used to determine historical variations in the biological pump, carbon cycle, and global climate.<ref name="Bates-2017" />
Dissolved barium's correlation with silicic acid can be seen both vertically and spatially.<ref name="Bates-2017">{{Cite journal|last1=Bates|first1=Stephanie L.|last2=Hendry|first2=Katharine R.|last3=Pryer|first3=Helena V.|last4=Kinsley|first4=Christopher W.|last5=Pyle|first5=Kimberley M.|last6=Woodward|first6=E. Malcolm S.|last7=Horner|first7=Tristan J.|date=2017-05-01|title=Barium isotopes reveal role of ocean circulation on barium cycling in the Atlantic|url=https://research-information.bris.ac.uk/ws/files/100680705/Bates_Ba_isotopes_FINAL.pdf|journal=Geochimica et Cosmochimica Acta|language=en|volume=204|pages=286–299|doi=10.1016/j.gca.2017.01.043|bibcode=2017GeCoA.204..286B|issn=0016-7037|hdl=1912/8676|s2cid=55559902 |hdl-access=free}}</ref> Particulate barium shows a strong correlation with [[Particulate organic matter|particulate organic carbon]] or POC.<ref name="Bates-2017" /> Barium is becoming more popular as a base for palaeoceanographic proxies.<ref name="Bates-2017" /> With both dissolved and particulate barium's links with silicic acid and POC, it can be used to determine historical variations in the biological pump, carbon cycle, and global climate.<ref name="Bates-2017" />


The barium particulate barite (BaSO<sub>4</sub>), as one of many proxies, can be used to provide a host of historical information on processes in different oceanic settings (water column, sediments, and hydrothermal sites).<ref name="Griffith-2012" /> In each setting there are differences in isotopic and elemental composition of the barite particulate.<ref name="Griffith-2012" /> Barite in the water column, known as marine or pelagic barite, reveals information on seawater chemistry variation over time.<ref name="Griffith-2012" /> Barite in sediments, known as diagenetic or cold seeps barite, gives information about sedimentary redox processes.<ref name="Griffith-2012" /> Barite formed via hydrothermal activity at hydrothermal vents, known as hydrothermal barite, reveals alterations in the condition of the earth's crust around those vents.<ref name="Griffith-2012" />
The barium particulate barite ({{chem2|BaSO4}}), as one of many proxies, can be used to provide a host of historical information on processes in different oceanic settings (water column, sediments, and hydrothermal sites).<ref name="Griffith-2012" /> In each setting there are differences in isotopic and elemental composition of the barite particulate.<ref name="Griffith-2012" /> Barite in the water column, known as marine or pelagic barite, reveals information on seawater chemistry variation over time.<ref name="Griffith-2012" /> Barite in sediments, known as diagenetic or cold seeps barite, gives information about sedimentary redox processes.<ref name="Griffith-2012" /> Barite formed via hydrothermal activity at hydrothermal vents, known as hydrothermal barite, reveals alterations in the condition of the earth's crust around those vents.<ref name="Griffith-2012" />


==Toxicity==
==Toxicity==

Revision as of 09:10, 4 June 2025

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Template:Infobox barium

Barium is a chemical element; it has symbol Ba and atomic number 56. It is the fifth element in group 2 and is a soft, silvery alkaline earth metal. Because of its high chemical reactivity, barium is never found in nature as a free element.

The most common minerals of barium are barite (barium sulfate, BaSO4) and witherite (barium carbonate, BaCO3). The name barium originates from the alchemical derivative "baryta", from Greek Script error: No such module "Lang". (Template:Transliteration), meaning 'heavy'. Baric is the adjectival form of barium. Barium was identified as a new element in 1772, but not reduced to a metal until 1808 with the advent of electrolysis.

Barium has few industrial applications. Historically, it was used as a getter for vacuum tubes and in oxide form as the emissive coating on indirectly heated cathodes. It is a component of YBCO (high-temperature superconductors) and electroceramics, and is added to steel and cast iron to reduce the size of carbon grains within the microstructure. Barium compounds are added to fireworks to impart a green color. Barium sulfate is used as an insoluble additive to oil well drilling fluid. In a purer form it is used as X-ray radiocontrast agents for imaging the human gastrointestinal tract. Water-soluble barium compounds are poisonous and have been used as rodenticides.

Characteristics

Physical properties

File:Barium 1.jpg
Oxidized barium

Barium is a soft, silvery-white metal, with a slight golden shade when ultrapure.[1]Template:Rp The silvery-white color of barium metal rapidly vanishes upon oxidation in air yielding a dark gray layer containing the oxide. Barium has a medium specific weight and high electrical conductivity. Because barium is difficult to purify, many of its properties have not been accurately determined.[1]Template:Rp

At room temperature and pressure, barium metal adopts a body-centered cubic structure, with a barium–barium distance of 503 picometers, expanding with heating at a rate of approximately 1.8Template:E/°C.[1]Template:Rp It is a soft metal with a Mohs hardness of 1.25.[1]Template:Rp Its melting temperature of Template:Convert[2]Template:Rp is intermediate between those of the lighter strontium (Template:Convert)[2]Template:Rp and heavier radium (Template:Convert);[2]Template:Rp however, its boiling point of Template:Convert exceeds that of strontium (Template:Convert).[2]Template:Rp The density (3.62 g/cm3)[2]Template:Rp is again intermediate between those of strontium (2.36 g/cm3)[2]Template:Rp and radium (≈5 g/cm3).[2]Template:Rp

Chemical reactivity

Barium is chemically similar to magnesium, calcium, and strontium, but more reactive. Its compounds are almost invariably found in the +2 oxidation state. As expected for a highly electropositive metal, barium's reaction with chalcogens is highly exothermic (release energy). Barium reacts with atmospheric oxygen in air at room temperature. For this reason, metallic barium is often stored under oil or in an inert atmosphere.[1]Template:Rp Reactions with other nonmetals, such as carbon, nitrogen, phosphorus, silicon, and hydrogen, proceed upon heating.[1]Template:Rp Reactions with water and alcohols are also exothermic and release hydrogen gas:[1]Template:Rp

Template:Chem2↑ (R is an alkyl group or a hydrogen atom)

Barium reacts with ammonia to form the electride Template:Chem2, which near room temperature gives the amide Template:Chem2.[3]

The metal is readily attacked by acids. Sulfuric acid is a notable exception because passivation stops the reaction by forming the insoluble barium sulfate on the surface.[4] Barium combines with several other metals, including aluminium, zinc, lead, and tin, forming intermetallic phases and alloys.[5]

Compounds

Selected alkaline earth and zinc salts densities, g/cm3
Template:Chem2 Template:Chem2 Template:Chem2 Template:Chem2 Template:Chem2 Template:Chem2 Template:Chem2 Template:Chem2
Template:Chem2[2]Template:Rp 3.34 2.59 3.18 2.15 2.96 2.83 2.9 1.7
Template:Chem2[2]Template:Rp 5.1 3.7 4.24 3.05 3.96 3.5 4.78 3.26
Template:Chem2[2]Template:Rp 5.72 4.3 4.89 3.89 4.49 4.29 4.96 4.16
Template:Chem2[2]Template:Rp 5.6 4.09 4.95 2.09 3.54 4.4 1.57

Barium salts are typically white when solid and colorless when dissolved.[6] They are denser than the strontium or calcium analogs, except for the halides (see table; zinc is given for comparison).

Barium hydroxide ("baryta") was known to alchemists, who produced it by heating barium carbonate. Unlike calcium hydroxide, it absorbs very little CO2 in aqueous solutions and is therefore insensitive to atmospheric fluctuations. This property is used in calibrating pH equipment.

Barium compounds burn with a green to pale green flame, which is an efficient test to detect a barium compound. The color results from spectral lines at 455.4, 493.4, 553.6, and 611.1 nm.[1]Template:Rp

Organobarium compounds are a growing field of knowledge: recently discovered are dialkylbariums and alkylhalobariums.[1]Template:Rp

Isotopes

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Barium found in the Earth's crust is a mixture of seven primordial nuclides, barium-130, 132, and 134 through 138.[7] Barium-130 undergoes very slow radioactive decay to xenon-130 by double beta plus decay, with a half-life of (0.5–2.7)×1021 years (about 1011 times the age of the universe). Its abundance is ≈0.1% that of natural barium.[7] Theoretically, barium-132 can similarly undergo double beta decay to xenon-132; this decay has not been detected.Template:NUBASE2016 The radioactivity of these isotopes is so weak that they pose no danger to life.

Of the stable isotopes, barium-138 composes 71.7% of all barium; other isotopes have decreasing abundance with decreasing mass number.[7]

In total, barium has 40 known isotopes, ranging in mass between 114 and 153. The most stable artificial radioisotope is barium-133 with a half-life of approximately 10.51 years. Five other isotopes have half-lives longer than a day.Template:NUBASE2016 Barium also has 10 meta states, of which barium-133m1 is the most stable with a half-life of about 39 hours.Template:NUBASE2016

History

File:Sir Humphry Davy, Bt by Sir Thomas Lawrence.jpg
Portrait of Sir Humphry Davy by Thomas Lawrence, 1821. Sir Humphry Davy was the first to isolate barium metal.

Alchemists in the early Middle Ages knew about some barium minerals. Smooth pebble-like stones of mineral baryte were found in volcanic rock near Bologna, Italy, and so were called "Bologna stones". Alchemists were attracted to them because after exposure to light they would glow for years.[8] The phosphorescent properties of baryte heated with organics were described by V. Casciorolus in 1602.[1]Template:Rp

Carl Scheele determined that baryte contained a new element in 1772, but could not isolate barium, only barium oxide. Johan Gottlieb Gahn also isolated barium oxide two years later in similar studies. Oxidized barium was at first called "barote" by Guyton de Morveau, a name that was changed by Antoine Lavoisier to baryte (in French) or baryta (in Latin). Also in the 18th century, English mineralogist William Withering noted a heavy mineral in the lead mines of Cumberland, now known to be witherite. Barium was first isolated by electrolysis of molten barium salts in 1808 by Sir Humphry Davy in England.[9] Davy, by analogy with calcium, named "barium" after baryta, with the "-ium" ending signifying a metallic element.[8] Robert Bunsen and Augustus Matthiessen obtained pure barium by electrolysis of a molten mixture of barium chloride and ammonium chloride.[10][11]

The production of pure oxygen in the Brin process was a large-scale application of barium peroxide in the 1880s, before it was replaced by electrolysis and fractional distillation of liquefied air in the early 1900s. In this process barium oxide reacts at Template:Convert with air to form barium peroxide, which decomposes above Template:Convert by releasing oxygen:[12][13]

Template:Chem2

Barium sulfate was first applied as a radiocontrast agent in X-ray imaging of the digestive system in 1908.[14]

Occurrence and production

The abundance of barium is 0.0425% in the Earth's crust and 13 μg/L in sea water. The primary commercial source of barium is baryte (also called barytes or heavy spar), a barium sulfate mineral.[1]Template:Rp with deposits in many parts of the world. Another commercial source, far less important than baryte, is witherite, barium carbonate. The main deposits are located in Britain, Romania, and the former USSR.[1]Template:Rp

Template:Multiple image The baryte reserves are estimated between 0.7 and 2 billion tonnes. The highest production, 8.3 million tonnes, was achieved in 1981, but only 7–8% was used for barium metal or compounds.[1]Template:Rp Baryte production has risen since the second half of the 1990s from 5.6 million tonnes in 1996 to 7.6 in 2005 and 7.8 in 2011. China accounts for more than 50% of this output, followed by India (14% in 2011), Morocco (8.3%), US (8.2%), Iran and Kazakhstan (2.6% each) and Turkey (2.5%).[15]

The mined ore is washed, crushed, classified, and separated from quartz. If the quartz penetrates too deeply into the ore, or the iron, zinc, or lead content is abnormally high, then froth flotation is used. The product is a 98% pure baryte (by mass); the purity should be no less than 95%, with a minimal content of iron and silicon dioxide.[1]Template:Rp It is then reduced by carbon to barium sulfide:[1]Template:Rp

Template:Chem2

The water-soluble barium sulfide is the starting point for other compounds: treating BaS with oxygen produces the sulfate, with nitric acid the nitrate, with aqueous carbon dioxide the carbonate, and so on.[1]Template:Rp The nitrate can be thermally decomposed to yield the oxide.[1]Template:Rp Barium metal is produced by reduction with aluminium at Template:Convert. The intermetallic compound BaAl4 is produced first:[1]Template:Rp

Template:Chem2

Template:Chem2 is an intermediate reacted with barium oxide to produce the metal. Note that not all barium is reduced.[1]Template:Rp

Template:Chem2

The remaining barium oxide reacts with the formed aluminium oxide:[1]Template:Rp

Template:Chem2

and the overall reaction is[1]Template:Rp

Template:Chem2

Barium vapor is condensed and packed into molds in an atmosphere of argon.[1]Template:Rp This method is used commercially, yielding ultrapure barium.[1]Template:Rp Commonly sold barium is about 99% pure, with main impurities being strontium and calcium (up to 0.8% and 0.25%) and other contaminants contributing less than 0.1%.[1]Template:Rp

A similar reaction with silicon at Template:Convert yields barium and barium metasilicate.[1]Template:Rp Electrolysis is not used because barium readily dissolves in molten halides and the product is rather impure.[1]Template:Rp

File:Benitoite HD.jpg
Benitoite crystals on natrolite. The mineral is named for the San Benito River in San Benito County where it was first found.

Gemstone

The barium mineral, benitoite (barium titanium silicate), occurs as a very rare blue fluorescent gemstone, and is the official state gem of California.

Barium in seawater

Barium exists in seawater as the Ba2+ ion with an average oceanic concentration of 109 nmol/kg.[16] Barium also exists in the ocean as BaSO4, or barite.[17] Barium has a nutrient-like profile[18] with a residence time of 10,000 years.[16]

Barium shows a relatively consistent concentration in upper ocean seawater, excepting regions of high river inputs and regions with strong upwelling.[19] There is little depletion of barium concentrations in the upper ocean for an ion with a nutrient-like profile, thus lateral mixing is important.[19] Barium isotopic values show basin-scale balances instead of local or short-term processes.[19]

Applications

Metal and alloys

Barium, as a metal or when alloyed with aluminium, is used to remove unwanted gases (gettering) from vacuum tubes, such as TV picture tubes.[1]Template:Rp Barium is suitable for this purpose because of its low vapor pressure and reactivity towards oxygen, nitrogen, carbon dioxide, and water; it can even partly remove noble gases by dissolving them in the crystal lattice. This application is gradually disappearing due to the rising popularity of the tubeless LCD, LED, and plasma sets.[1]Template:Rp

Other uses of elemental barium are minor and include an additive to silumin (aluminium–silicon alloys) that refines their structure, as well as[1]Template:Rp

Barium sulfate and baryte

File:BariumXray.jpg
Amoebiasis as seen in a radiograph of a barium-filled colon

Barium sulfate (the mineral baryte, BaSO4) is important to the petroleum industry as a drilling fluid in oil and gas wells.[2]Template:Rp The precipitate of the compound (called "blanc fixe", from the French for "permanent white") is used in paints and varnishes; as a filler in ringing ink, plastics, and rubbers; as a paper coating pigment; and in nanoparticles, to improve physical properties of some polymers, such as epoxies.[1]Template:Rp

Barium sulfate has a low toxicity and relatively high density of ca. 4.5 g/cm3 (and thus opacity to X-rays). For this reason it is used as a radiocontrast agent in X-ray imaging of the digestive system ("barium meals" and "barium enemas").[2]Template:Rp Lithopone, a pigment that contains barium sulfate and zinc sulfide, is a permanent white with good covering power that does not darken when exposed to sulfides.[20]

Other barium compounds

File:2006 Fireworks 1.JPG
Green barium fireworks

Other compounds of barium find only niche applications, limited by the toxicity of Template:Chem2 ions (see Template:Section link), which is not a problem for the insoluble Template:Chem2.

Palaeoceanography

The lateral mixing of barium is caused by water mass mixing and ocean circulation.[26] Global ocean circulation reveals a strong correlation between dissolved barium and silicic acid.[26] The large-scale ocean circulation combined with remineralization of barium show a similar correlation between dissolved barium and ocean alkalinity.[26]

Dissolved barium's correlation with silicic acid can be seen both vertically and spatially.[27] Particulate barium shows a strong correlation with particulate organic carbon or POC.[27] Barium is becoming more popular as a base for palaeoceanographic proxies.[27] With both dissolved and particulate barium's links with silicic acid and POC, it can be used to determine historical variations in the biological pump, carbon cycle, and global climate.[27]

The barium particulate barite (Template:Chem2), as one of many proxies, can be used to provide a host of historical information on processes in different oceanic settings (water column, sediments, and hydrothermal sites).[17] In each setting there are differences in isotopic and elemental composition of the barite particulate.[17] Barite in the water column, known as marine or pelagic barite, reveals information on seawater chemistry variation over time.[17] Barite in sediments, known as diagenetic or cold seeps barite, gives information about sedimentary redox processes.[17] Barite formed via hydrothermal activity at hydrothermal vents, known as hydrothermal barite, reveals alterations in the condition of the earth's crust around those vents.[17]

Toxicity

Template:Chembox Soluble barium compounds have LD50 near 10 mg/kg (oral rats). Symptoms include "convulsions... paralysis of the peripheral nerve system ... severe inflammation of the gastrointestinal tract".[1]Template:Rp The insoluble sulfate is nontoxic and is not classified as a dangerous goods in transport regulations.[1]Template:Rp

Little is known about the long term effects of barium exposure.[28] The US EPA considers it unlikely that barium is carcinogenic when consumed orally. Inhaled dust containing insoluble barium compounds can accumulate in the lungs, causing a benign condition called baritosis.[29]

Barium carbonate has been used as a rodenticide.[30] Though considered obsolete, it may still be in use in some countries.[31]

See also

References

Template:Reflist

External links

Template:Barium compounds Template:Periodic table (navbox) Template:Alkaline earth metals Template:Subject bar Template:Authority control Template:Good article

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  15. Miller, M. M. Barite. USGS.gov
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