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    Strontium

    Author: www.NiNa.Az
    Feb 06, 2025 / 08:59

    Strontium is a chemical element it has symbol Sr and atomic number 38 An alkaline earth metal strontium is a soft silver

    Strontium
    Strontium
    Strontium
    www.NiNa.Azhttps://www.english.nina.az/author.html

    Strontium is a chemical element; it has symbol Sr and atomic number 38. An alkaline earth metal, strontium is a soft silver-white yellowish metallic element that is highly chemically reactive. The metal forms a dark oxide layer when it is exposed to air. Strontium has physical and chemical properties similar to those of its two vertical neighbors in the periodic table, calcium and barium. It occurs naturally mainly in the minerals celestine and strontianite, and is mostly mined from these.

    Strontium, 38Sr
    image
    Strontium
    Pronunciation
    • /ˈstrɒntiəm/
      (STRON-tee-əm)
    • /ˈstrɒnʃiəm/
      (STRON-shee-əm)
    Appearancesilvery white metallic; with a pale yellow tint
    Standard atomic weight Ar°(Sr)
    • 87.62±0.01
    • 87.62±0.01 (abridged)
    Strontium in the periodic table
    Hydrogen Helium
    Lithium Beryllium Boron Carbon Nitrogen Oxygen Fluorine Neon
    Sodium Magnesium Aluminium Silicon Phosphorus Sulfur Chlorine Argon
    Potassium Calcium Scandium Titanium Vanadium Chromium Manganese Iron Cobalt Nickel Copper Zinc Gallium Germanium Arsenic Selenium Bromine Krypton
    Rubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Silver Cadmium Indium Tin Antimony Tellurium Iodine Xenon
    Caesium Barium Lanthanum Cerium Praseodymium Neodymium Promethium Samarium Europium Gadolinium Terbium Dysprosium Holmium Erbium Thulium Ytterbium Lutetium Hafnium Tantalum Tungsten Rhenium Osmium Iridium Platinum Gold Mercury (element) Thallium Lead Bismuth Polonium Astatine Radon
    Francium Radium Actinium Thorium Protactinium Uranium Neptunium Plutonium Americium Curium Berkelium Californium Einsteinium Fermium Mendelevium Nobelium Lawrencium Rutherfordium Dubnium Seaborgium Bohrium Hassium Meitnerium Darmstadtium Roentgenium Copernicium Nihonium Flerovium Moscovium Livermorium Tennessine Oganesson
    		Ca
    ↑
    Sr
    ↓
    Ba
    rubidium ← strontium → yttrium
    Atomic number (Z)38
    Groupgroup 2 (alkaline earth metals)
    Periodperiod 5
    Block  s-block
    Electron configuration[Kr] 5s2
    Electrons per shell2, 8, 18, 8, 2
    Physical properties
    Phase at STPsolid
    Melting point1050 K ​(777 °C, ​1431 °F)
    Boiling point1650 K ​(1377 °C, ​2511 °F)
    Density (at 20° C)2.582 g/cm3
    when liquid (at m.p.)2.375 g/cm3
    Heat of fusion7.43 kJ/mol
    Heat of vaporization141 kJ/mol
    Molar heat capacity26.4 J/(mol·K)
    Vapor pressure
    P (Pa) 1 10 100 1 k 10 k 100 k
    at T (K) 796 882 990 1139 1345 1646
    Atomic properties
    Oxidation statescommon: +2
    +1
    ElectronegativityPauling scale: 0.95
    Ionization energies
    • 1st: 549.5 kJ/mol
    • 2nd: 1064.2 kJ/mol
    • 3rd: 4138 kJ/mol
    Atomic radiusempirical: 215 pm
    Covalent radius195±10 pm
    Van der Waals radius249 pm
    image
    Spectral lines of strontium
    Other properties
    Natural occurrenceprimordial
    Crystal structure ​face-centered cubic (fcc) (cF4)
    Lattice constant
    image
    a = 608.6 pm (at 20 °C)
    Thermal expansion22.55×10−6/K (at 20 °C)
    Thermal conductivity35.4 W/(m⋅K)
    Electrical resistivity132 nΩ⋅m (at 20 °C)
    Magnetic orderingparamagnetic
    Molar magnetic susceptibility−92.0×10−6 cm3/mol (298 K)
    Young's modulus15.7 GPa
    Shear modulus6.03 GPa
    Poisson ratio0.28
    Mohs hardness1.5
    CAS Number7440-24-6
    History
    Namingafter the mineral strontianite, itself named after Strontian, Scotland
    DiscoveryWilliam Cruickshank (1787)
    First isolationHumphry Davy (1808)
    Isotopes of strontium
    • v
    • e
    Main isotopes Decay
    abun­dance half-life (t1/2) mode pro­duct
    82Sr synth 25.36 d ε 82Rb
    83Sr synth 1.35 d ε 83Rb
    β+ 83Rb
    γ –
    84Sr 0.56% stable
    85Sr synth 64.84 d ε 85Rb
    γ –
    86Sr 9.86% stable
    87Sr 7% stable
    88Sr 82.6% stable
    89Sr synth 50.52 d β− 89Y
    90Sr trace 28.90 y β− 90Y
    image Category: Strontium
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    Both strontium and strontianite are named after Strontian, a village in Scotland near which the mineral was discovered in 1790 by Adair Crawford and William Cruickshank; it was identified as a new element the next year from its crimson-red flame test color. Strontium was first isolated as a metal in 1808 by Humphry Davy using the then newly discovered process of electrolysis. During the 19th century, strontium was mostly used in the production of sugar from sugar beets (see strontian process). At the peak of production of television cathode-ray tubes, as much as 75% of strontium consumption in the United States was used for the faceplate glass. With the replacement of cathode-ray tubes with other display methods, consumption of strontium has dramatically declined.

    While natural strontium (which is mostly the isotope strontium-88) is stable, the synthetic strontium-90 is radioactive and is one of the most dangerous components of nuclear fallout, as strontium is absorbed by the body in a similar manner to calcium. Natural stable strontium, on the other hand, is not hazardous to health.

    Characteristics

    image
    Oxidized dendritic strontium

    Strontium is a divalent silvery metal with a pale yellow tint whose properties are mostly intermediate between and similar to those of its group neighbors calcium and barium. It is softer than calcium and harder than barium. Its melting (777 °C) and boiling (1377 °C) points are lower than those of calcium (842 °C and 1484 °C respectively); barium continues this downward trend in the melting point (727 °C), but not in the boiling point (1900 °C). The density of strontium (2.64 g/cm3) is similarly intermediate between those of calcium (1.54 g/cm3) and barium (3.594 g/cm3). Three allotropes of metallic strontium exist, with transition points at 235 and 540 °C.[citation needed]

    The standard electrode potential for the Sr2+/Sr couple is −2.89 V, approximately midway between those of the Ca2+/Ca (−2.84 V) and Ba2+/Ba (−2.92 V) couples, and close to those of the neighboring alkali metals. Strontium is intermediate between calcium and barium in its reactivity toward water, with which it reacts on contact to produce strontium hydroxide and hydrogen gas. Strontium metal burns in air to produce both strontium oxide and strontium nitride, but since it does not react with nitrogen below 380 °C, at room temperature it forms only the oxide spontaneously. Besides the simple oxide SrO, the peroxide SrO2 can be made by direct oxidation of strontium metal under a high pressure of oxygen, and there is some evidence for a yellow superoxide Sr(O2)2.Strontium hydroxide, Sr(OH)2, is a strong base, though it is not as strong as the hydroxides of barium or the alkali metals. All four dihalides of strontium are known.

    Due to the large size of the heavy s-block elements, including strontium, a vast range of coordination numbers is known, from 2, 3, or 4 all the way to 22 or 24 in SrCd11 and SrZn13. The Sr2+ ion is quite large, so that high coordination numbers are the rule. The large size of strontium and barium plays a significant part in stabilising strontium complexes with polydentate macrocyclic ligands such as crown ethers: for example, while 18-crown-6 forms relatively weak complexes with calcium and the alkali metals, its strontium and barium complexes are much stronger.

    Organostrontium compounds contain one or more strontium–carbon bonds. They have been reported as intermediates in Barbier-type reactions. Although strontium is in the same group as magnesium, and organomagnesium compounds are very commonly used throughout chemistry, organostrontium compounds are not similarly widespread because they are more difficult to make and more reactive. Organostrontium compounds tend to be more similar to organoeuropium or organosamarium compounds due to the similar ionic radii of these elements (Sr2+ 118 pm; Eu2+ 117 pm; Sm2+ 122 pm). Most of these compounds can only be prepared at low temperatures; bulky ligands tend to favor stability. For example, strontium dicyclopentadienyl, Sr(C5H5)2, must be made by directly reacting strontium metal with mercurocene or cyclopentadiene itself; replacing the C5H5 ligand with the bulkier C5(CH3)5 ligand on the other hand increases the compound's solubility, volatility, and kinetic stability.

    Because of its extreme reactivity with oxygen and water, strontium occurs naturally only in compounds with other elements, such as in the minerals strontianite and celestine. It is kept under a liquid hydrocarbon such as mineral oil or kerosene to prevent oxidation; freshly exposed strontium metal rapidly turns a yellowish color with the formation of the oxide. Finely powdered strontium metal is pyrophoric, meaning that it will ignite spontaneously in air at room temperature. Volatile strontium salts impart a bright red color to flames, and these salts are used in pyrotechnics and in the production of flares. Like calcium and barium, as well as the alkali metals and the divalent lanthanides europium and ytterbium, strontium metal dissolves directly in liquid ammonia to give a dark blue solution of solvated electrons.

    Isotopes

    Natural strontium is a mixture of four stable isotopes: 84Sr, 86Sr, 87Sr, and 88Sr. On these isotopes, 88Sr is the most abundant, makes up about 82.6% of all natural strontium, though the abundance varies due to the production of radiogenic 87Sr as the daughter of long-lived beta-decaying 87Rb. This is the basis of rubidium–strontium dating. Of the unstable isotopes, the primary decay mode of the isotopes lighter than 85Sr is electron capture or positron emission to isotopes of rubidium, and that of the isotopes heavier than 88Sr is electron emission to isotopes of yttrium. Of special note are 89Sr and 90Sr. The former has a half-life of 50.6 days and is used to treat bone cancer due to strontium's chemical similarity and hence ability to replace calcium. While 90Sr (half-life 28.90 years) has been used similarly, it is also an isotope of concern in fallout from nuclear weapons and nuclear accidents due to its production as a fission product. Its presence in bones can cause bone cancer, cancer of nearby tissues, and leukemia. The 1986 Chernobyl nuclear accident contaminated about 30,000 km2 with greater than 10 kBq/m2 with 90Sr, which accounts for about 5% of the 90Sr which was in the reactor core.

    History

    image
    Flame test for strontium

    Strontium is named after the Scottish village of Strontian (Scottish Gaelic: Sròn an t-Sìthein), where it was discovered in the ores of the lead mines.

    In 1790, Adair Crawford, a physician engaged in the preparation of barium, and his colleague William Cruickshank, recognised that the Strontian ores exhibited properties that differed from those in other "heavy spars" sources. This allowed Crawford to conclude on page 355 "... it is probable indeed, that the scotch mineral is a new species of earth which has not hitherto been sufficiently examined." The physician and mineral collector Friedrich Gabriel Sulzer analysed together with Johann Friedrich Blumenbach the mineral from Strontian and named it strontianite. He also came to the conclusion that it was distinct from the witherite and contained a new earth (neue Grunderde). In 1793 Thomas Charles Hope, a professor of chemistry at the University of Glasgow studied the mineral and proposed the name strontites. He confirmed the earlier work of Crawford and recounted: "... Considering it a peculiar earth I thought it necessary to give it an name. I have called it Strontites, from the place it was found; a mode of derivation in my opinion, fully as proper as any quality it may possess, which is the present fashion." The element was eventually isolated by Sir Humphry Davy in 1808 by the electrolysis of a mixture containing strontium chloride and mercuric oxide, and announced by him in a lecture to the Royal Society on 30 June 1808. In keeping with the naming of the other alkaline earths, he changed the name to strontium.

    The first large-scale application of strontium was in the production of sugar from sugar beet. Although a crystallisation process using strontium hydroxide was patented by Augustin-Pierre Dubrunfaut in 1849 the large scale introduction came with the improvement of the process in the early 1870s. The German sugar industry used the process well into the 20th century. Before World War I the beet sugar industry used 100,000 to 150,000 tons of strontium hydroxide for this process per year. The strontium hydroxide was recycled in the process, but the demand to substitute losses during production was high enough to create a significant demand initiating mining of strontianite in the Münsterland. The mining of strontianite in Germany ended when mining of the celestine deposits in Gloucestershire started. These mines supplied most of the world strontium supply from 1884 to 1941. Although the celestine deposits in the Granada basin were known for some time the large scale mining did not start before the 1950s.

    During atmospheric nuclear weapons testing, it was observed that strontium-90 is one of the nuclear fission products with a relatively high yield. The similarity to calcium and the chance that the strontium-90 might become enriched in bones made research on the metabolism of strontium an important topic.

    Occurrence

    See also: Category:Strontium minerals
    image
    The mineral celestine (SrSO4)

    Strontium commonly occurs in nature, being the 15th most abundant element on Earth (its heavier congener barium being the 14th), estimated to average approximately 360 parts per million in the Earth's crust and is found chiefly as the sulfate mineral celestine (SrSO4) and the carbonate strontianite (SrCO3). Of the two, celestine occurs much more frequently in deposits of sufficient size for mining. Because strontium is used most often in the carbonate form, strontianite would be the more useful of the two common minerals, but few deposits have been discovered that are suitable for development. Because of the way it reacts with air and water, strontium only exists in nature when combined to form minerals. Naturally occurring strontium is stable, but its synthetic isotope Sr-90 is only produced by nuclear fallout.

    In groundwater strontium behaves chemically much like calcium. At intermediate to acidic pH Sr2+ is the dominant strontium species. In the presence of calcium ions, strontium commonly forms coprecipitates with calcium minerals such as calcite and anhydrite at an increased pH. At intermediate to acidic pH, dissolved strontium is bound to soil particles by cation exchange.

    The mean strontium content of ocean water is 8 mg/L. At a concentration between 82 and 90 μmol/L of strontium, the concentration is considerably lower than the calcium concentration, which is normally between 9.6 and 11.6 mmol/L. It is nevertheless much higher than that of barium, 13 μg/L.

    Production

    The major producers of strontium as celestine as of January 2024 are Spain (200,000 t), Iran (200,000 t), China (80,000 t), Mexico (35,000 t); and Argentina (700 t). Although strontium deposits occur widely in the United States, they have not been mined since 1959.

    A large proportion of mined celestine (SrSO4) is converted to the carbonate by two processes. Either the celestine is directly leached with sodium carbonate solution or the celestine is roasted with coal to form the sulfide. The second stage produces a dark-coloured material containing mostly strontium sulfide. This so-called "black ash" is dissolved in water and filtered. Strontium carbonate is precipitated from the strontium sulfide solution by introduction of carbon dioxide. The sulfate is reduced to the sulfide by the carbothermic reduction:

    SrSO4 + 2 C → SrS + 2 CO2

    About 300,000 tons are processed in this way annually.

    The metal is produced commercially by reducing strontium oxide with aluminium. The strontium is distilled from the mixture. Strontium metal can also be prepared on a small scale by electrolysis of a solution of strontium chloride in molten potassium chloride:

    Sr2+ + 2
    e−
     → Sr
    2 Cl− → Cl2 + 2
    e−

    Applications

    image
    Most of the world's production of strontium used to be consumed in the production of cathode-ray tube (CRT) displays. The glass contained strontium and barium oxide to block X-rays.

    Consuming 75% of production, the primary use for strontium was in glass for colour television cathode-ray tubes, where it prevented X-ray emission. This application for strontium has been declining because CRTs are being replaced by other display methods. This decline has a significant influence on the mining and refining of strontium. All parts of the CRT must absorb X-rays. In the neck and the funnel of the tube, lead glass is used for this purpose, but this type of glass shows a browning effect due to the interaction of the X-rays with the glass. Therefore, the front panel is made from a different glass mixture with strontium and barium to absorb the X-rays. The average values for the glass mixture determined for a recycling study in 2005 is 8.5% strontium oxide and 10% barium oxide.

    Because strontium is so similar to calcium, it is incorporated in the bone. All four stable isotopes are incorporated, in roughly the same proportions they are found in nature. However, the actual distribution of the isotopes tends to vary greatly from one geographical location to another. Thus, analyzing the bone of an individual can help determine the region it came from. This approach helps to identify the ancient migration patterns and the origin of commingled human remains in battlefield burial sites.

    87Sr/86Sr ratios are commonly used to determine the likely provenance areas of sediment in natural systems, especially in marine and fluvial environments. Dasch (1969) showed that surface sediments of Atlantic displayed 87Sr/86Sr ratios that could be regarded as bulk averages of the 87Sr/86Sr ratios of geological terrains from adjacent landmasses. A good example of a fluvial-marine system to which Sr isotope provenance studies have been successfully employed is the River Nile-Mediterranean system. Due to the differing ages of the rocks that constitute the majority of the Blue and White Nile, catchment areas of the changing provenance of sediment reaching the River Nile Delta and East Mediterranean Sea can be discerned through strontium isotopic studies. Such changes are climatically controlled in the Late Quaternary.

    More recently, 87Sr/86Sr ratios have also been used to determine the source of ancient archaeological materials such as timbers and corn in Chaco Canyon, New Mexico.87Sr/86Sr ratios in teeth may also be used to track animal migrations.

    Strontium aluminate is frequently used in glow in the dark toys, as it is chemically and biologically inert.

    image
    Strontium salts are added to fireworks in order to create red colors.

    Strontium carbonate and other strontium salts are added to fireworks to give a deep red colour. This same effect identifies strontium cations in the flame test. Fireworks consume about 5% of the world's production. Strontium carbonate is used in the manufacturing of hard ferrite magnets.

    Strontium chloride is sometimes used in toothpastes for sensitive teeth. One popular brand includes 10% total strontium chloride hexahydrate by weight. Small amounts are used in the refining of zinc to remove small amounts of lead impurities. The metal itself has a limited use as a getter, to remove unwanted gases in vacuums by reacting with them, although barium may also be used for this purpose.

    The ultra-narrow optical transition between the [Kr]5s21S0 electronic ground state and the metastable [Kr]5s5p 3P0 excited state of 87Sr is one of the leading candidates for the future re-definition of the second in terms of an optical transition as opposed to the current definition derived from a microwave transition between different hyperfine ground states of 133Cs. Current optical atomic clocks operating on this transition already surpass the precision and accuracy of the current definition of the second.

    Radioactive strontium

    image
    RTGs from Soviet-era lighthouses

    89Sr is the active ingredient in Metastron, a radiopharmaceutical used for bone pain secondary to metastatic bone cancer. The strontium is processed like calcium by the body, preferentially incorporating it into bone at sites of increased osteogenesis. This localization focuses the radiation exposure on the cancerous lesion.

    90Sr has been used as a power source for radioisotope thermoelectric generators (RTGs). 90Sr produces approximately 0.93 watts of heat per gram (it is lower for the form of 90Sr used in RTGs, which is strontium fluoride). However, 90Sr has one third the lifetime and a lower density than 238Pu, another RTG fuel. The main advantage of 90Sr is that it is significantly cheaper than 238Pu and is found in nuclear waste. The latter must be prepared by irradiating 237Np with neutrons then separating the modest amounts of 238Pu. The principal disadvantage of 90Sr is the high energy beta particles produce Bremsstrahlung as they encounter nuclei of other nearby heavy atoms such as adjacent strontium. This is mostly in the range of X-rays. Thus strong beta emitters also emit significant secondary X-rays in most cases. This requires significant shielding measures which complicates the design of RTGs using 90Sr. The Soviet Union deployed nearly 1000 of these RTGs on its northern coast as a power source for lighthouses and meteorology stations.

    Biological role

    Strontium
    Hazards
    GHS labelling:
    Pictograms
    		 imageimage
    Signal word
    		 Danger
    Hazard statements
    		 H261, H315
    Precautionary statements
    		 P223, P231+P232, P370+P378, P422
    NFPA 704 (fire diamond)
    imageFlammability 0: Will not burn. E.g. waterInstability 2: Undergoes violent chemical change at elevated temperatures and pressures, reacts violently with water, or may form explosive mixtures with water. E.g. white phosphorusSpecial hazard W: Reacts with water in an unusual or dangerous manner. E.g. sodium, sulfuric acid
    2
    0
    2
    W

    Acantharea, a relatively large group of marine radiolarian protozoa, produce intricate mineral skeletons composed of strontium sulfate. In biological systems, calcium is substituted to a small extent by strontium. In the human body, most of the absorbed strontium is deposited in the bones. The ratio of strontium to calcium in human bones is between 1:1000 and 1:2000, roughly in the same range as in the blood serum.

    Effect on the human body

    The human body absorbs strontium as if it were its lighter congener calcium. Because the elements are chemically very similar, stable strontium isotopes do not pose a significant health threat. The average human has an intake of about two milligrams of strontium a day. In adults, strontium consumed tends to attach only to the surface of bones, but in children, strontium can replace calcium in the mineral of the growing bones and thus lead to bone growth problems.

    The biological half-life of strontium in humans has variously been reported as from 14 to 600 days, 1,000 days, 18 years, 30 years and, at an upper limit, 49 years. The wide-ranging published biological half-life figures are explained by strontium's complex metabolism within the body. However, by averaging all excretion paths, the overall biological half-life is estimated to be about 18 years. The elimination rate of strontium is strongly affected by age and sex, due to differences in bone metabolism.

    The drug strontium ranelate aids bone growth, increases bone density, and lessens the incidence of vertebral, peripheral, and hip fractures. However, strontium ranelate also increases the risk of venous thromboembolism, pulmonary embolism, and serious cardiovascular disorders, including myocardial infarction. Its use is therefore now restricted. Its beneficial effects are also questionable, since the increased bone density is partially caused by the increased density of strontium over the calcium which it replaces. Strontium also bioaccumulates in the body. Despite restrictions on strontium ranelate, strontium is still contained in some supplements. There is not much scientific evidence on risks of strontium chloride when taken by mouth. Those with a personal or family history of blood clotting disorders are advised to avoid strontium.

    Strontium has been shown to inhibit sensory irritation when applied topically to the skin. Topically applied, strontium has been shown to accelerate the recovery rate of the epidermal permeability barrier (skin barrier).

    Nuclear waste

    Strontium-90 is a radioactive fission product produced by nuclear reactors used in nuclear power. It is a major component of high level radioactivity of nuclear waste and spent nuclear fuel. Its 29-year half life is short enough that its decay heat has been used to power arctic lighthouses, but long enough that it can take hundreds of years to decay to safe levels. Exposure from contaminated water and food may increase the risk of leukemia, bone cancer and primary hyperparathyroidism.

    Remediation

    Algae has shown selectivity for strontium in studies, where most plants used in bioremediation have not shown selectivity between calcium and strontium, often becoming saturated with calcium, which is greater in quantity and also present in nuclear waste.

    Researchers have looked at the bioaccumulation of strontium by Scenedesmus spinosus (algae) in simulated wastewater. The study claims a highly selective biosorption capacity for strontium of S. spinosus, suggesting that it may be appropriate for use in treating nuclear wastewater.

    A study of the pond alga Closterium moniliferum using non-radioactive strontium found that varying the ratio of barium to strontium in water improved strontium selectivity.

    See also

    Portal:
    • image Chemistry

    References

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    Bibliography

    • Greenwood, Norman N.; Earnshaw, Alan (1997). Chemistry of the Elements (2nd ed.). Butterworth-Heinemann. ISBN 978-0-08-037941-8.

    External links

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    • WebElements.com – Strontium
    • Strontium at The Periodic Table of Videos (University of Nottingham)

    Strontium is a chemical element it has symbol Sr and atomic number 38 An alkaline earth metal strontium is a soft silver white yellowish metallic element that is highly chemically reactive The metal forms a dark oxide layer when it is exposed to air Strontium has physical and chemical properties similar to those of its two vertical neighbors in the periodic table calcium and barium It occurs naturally mainly in the minerals celestine and strontianite and is mostly mined from these Strontium 38SrStrontiumPronunciation ˈ s t r ɒ n t i e m STRON tee em ˈ s t r ɒ n ʃ i e m STRON shee em Appearancesilvery white metallic with a pale yellow tintStandard atomic weight Ar Sr 87 62 0 0187 62 0 01 abridged Strontium in the periodic tableHydrogen HeliumLithium Beryllium Boron Carbon Nitrogen Oxygen Fluorine NeonSodium Magnesium Aluminium Silicon Phosphorus Sulfur Chlorine ArgonPotassium Calcium Scandium Titanium Vanadium Chromium Manganese Iron Cobalt Nickel Copper Zinc Gallium Germanium Arsenic Selenium Bromine KryptonRubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Silver Cadmium Indium Tin Antimony Tellurium Iodine XenonCaesium Barium Lanthanum Cerium Praseodymium Neodymium Promethium Samarium Europium Gadolinium Terbium Dysprosium Holmium Erbium Thulium Ytterbium Lutetium Hafnium Tantalum Tungsten Rhenium Osmium Iridium Platinum Gold Mercury element Thallium Lead Bismuth Polonium Astatine RadonFrancium Radium Actinium Thorium Protactinium Uranium Neptunium Plutonium Americium Curium Berkelium Californium Einsteinium Fermium Mendelevium Nobelium Lawrencium Rutherfordium Dubnium Seaborgium Bohrium Hassium Meitnerium Darmstadtium Roentgenium Copernicium Nihonium Flerovium Moscovium Livermorium Tennessine Oganesson Ca Sr Barubidium strontium yttriumAtomic number Z 38Groupgroup 2 alkaline earth metals Periodperiod 5Block s blockElectron configuration Kr 5s2Electrons per shell2 8 18 8 2Physical propertiesPhase at STPsolidMelting point1050 K 777 C 1431 F Boiling point1650 K 1377 C 2511 F Density at 20 C 2 582 g cm3when liquid at m p 2 375 g cm3Heat of fusion7 43 kJ molHeat of vaporization141 kJ molMolar heat capacity26 4 J mol K Vapor pressureP Pa 1 10 100 1 k 10 k 100 kat T K 796 882 990 1139 1345 1646Atomic propertiesOxidation statescommon 2 1ElectronegativityPauling scale 0 95Ionization energies1st 549 5 kJ mol2nd 1064 2 kJ mol3rd 4138 kJ molAtomic radiusempirical 215 pmCovalent radius195 10 pmVan der Waals radius249 pmSpectral lines of strontiumOther propertiesNatural occurrenceprimordialCrystal structure face centered cubic fcc cF4 Lattice constanta 608 6 pm at 20 C Thermal expansion22 55 10 6 K at 20 C Thermal conductivity35 4 W m K Electrical resistivity132 nW m at 20 C Magnetic orderingparamagneticMolar magnetic susceptibility 92 0 10 6 cm3 mol 298 K Young s modulus15 7 GPaShear modulus6 03 GPaPoisson ratio0 28Mohs hardness1 5CAS Number7440 24 6HistoryNamingafter the mineral strontianite itself named after Strontian ScotlandDiscoveryWilliam Cruickshank 1787 First isolationHumphry Davy 1808 Isotopes of strontiumveMain isotopes Decayabun dance half life t1 2 mode pro duct82Sr synth 25 36 d e 82Rb83Sr synth 1 35 d e 83Rbb 83Rbg 84Sr 0 56 stable85Sr synth 64 84 d e 85Rbg 86Sr 9 86 stable87Sr 7 stable88Sr 82 6 stable89Sr synth 50 52 d b 89Y90Sr trace 28 90 y b 90Y Category Strontium viewtalkedit references Both strontium and strontianite are named after Strontian a village in Scotland near which the mineral was discovered in 1790 by Adair Crawford and William Cruickshank it was identified as a new element the next year from its crimson red flame test color Strontium was first isolated as a metal in 1808 by Humphry Davy using the then newly discovered process of electrolysis During the 19th century strontium was mostly used in the production of sugar from sugar beets see strontian process At the peak of production of television cathode ray tubes as much as 75 of strontium consumption in the United States was used for the faceplate glass With the replacement of cathode ray tubes with other display methods consumption of strontium has dramatically declined While natural strontium which is mostly the isotope strontium 88 is stable the synthetic strontium 90 is radioactive and is one of the most dangerous components of nuclear fallout as strontium is absorbed by the body in a similar manner to calcium Natural stable strontium on the other hand is not hazardous to health CharacteristicsOxidized dendritic strontium Strontium is a divalent silvery metal with a pale yellow tint whose properties are mostly intermediate between and similar to those of its group neighbors calcium and barium It is softer than calcium and harder than barium Its melting 777 C and boiling 1377 C points are lower than those of calcium 842 C and 1484 C respectively barium continues this downward trend in the melting point 727 C but not in the boiling point 1900 C The density of strontium 2 64 g cm3 is similarly intermediate between those of calcium 1 54 g cm3 and barium 3 594 g cm3 Three allotropes of metallic strontium exist with transition points at 235 and 540 C citation needed The standard electrode potential for the Sr2 Sr couple is 2 89 V approximately midway between those of the Ca2 Ca 2 84 V and Ba2 Ba 2 92 V couples and close to those of the neighboring alkali metals Strontium is intermediate between calcium and barium in its reactivity toward water with which it reacts on contact to produce strontium hydroxide and hydrogen gas Strontium metal burns in air to produce both strontium oxide and strontium nitride but since it does not react with nitrogen below 380 C at room temperature it forms only the oxide spontaneously Besides the simple oxide SrO the peroxide SrO2 can be made by direct oxidation of strontium metal under a high pressure of oxygen and there is some evidence for a yellow superoxide Sr O2 2 Strontium hydroxide Sr OH 2 is a strong base though it is not as strong as the hydroxides of barium or the alkali metals All four dihalides of strontium are known Due to the large size of the heavy s block elements including strontium a vast range of coordination numbers is known from 2 3 or 4 all the way to 22 or 24 in SrCd11 and SrZn13 The Sr2 ion is quite large so that high coordination numbers are the rule The large size of strontium and barium plays a significant part in stabilising strontium complexes with polydentate macrocyclic ligands such as crown ethers for example while 18 crown 6 forms relatively weak complexes with calcium and the alkali metals its strontium and barium complexes are much stronger Organostrontium compounds contain one or more strontium carbon bonds They have been reported as intermediates in Barbier type reactions Although strontium is in the same group as magnesium and organomagnesium compounds are very commonly used throughout chemistry organostrontium compounds are not similarly widespread because they are more difficult to make and more reactive Organostrontium compounds tend to be more similar to organoeuropium or organosamarium compounds due to the similar ionic radii of these elements Sr2 118 pm Eu2 117 pm Sm2 122 pm Most of these compounds can only be prepared at low temperatures bulky ligands tend to favor stability For example strontium dicyclopentadienyl Sr C5H5 2 must be made by directly reacting strontium metal with mercurocene or cyclopentadiene itself replacing the C5H5 ligand with the bulkier C5 CH3 5 ligand on the other hand increases the compound s solubility volatility and kinetic stability Because of its extreme reactivity with oxygen and water strontium occurs naturally only in compounds with other elements such as in the minerals strontianite and celestine It is kept under a liquid hydrocarbon such as mineral oil or kerosene to prevent oxidation freshly exposed strontium metal rapidly turns a yellowish color with the formation of the oxide Finely powdered strontium metal is pyrophoric meaning that it will ignite spontaneously in air at room temperature Volatile strontium salts impart a bright red color to flames and these salts are used in pyrotechnics and in the production of flares Like calcium and barium as well as the alkali metals and the divalent lanthanides europium and ytterbium strontium metal dissolves directly in liquid ammonia to give a dark blue solution of solvated electrons Isotopes Natural strontium is a mixture of four stable isotopes 84Sr 86Sr 87Sr and 88Sr On these isotopes 88Sr is the most abundant makes up about 82 6 of all natural strontium though the abundance varies due to the production of radiogenic 87Sr as the daughter of long lived beta decaying 87Rb This is the basis of rubidium strontium dating Of the unstable isotopes the primary decay mode of the isotopes lighter than 85Sr is electron capture or positron emission to isotopes of rubidium and that of the isotopes heavier than 88Sr is electron emission to isotopes of yttrium Of special note are 89Sr and 90Sr The former has a half life of 50 6 days and is used to treat bone cancer due to strontium s chemical similarity and hence ability to replace calcium While 90Sr half life 28 90 years has been used similarly it is also an isotope of concern in fallout from nuclear weapons and nuclear accidents due to its production as a fission product Its presence in bones can cause bone cancer cancer of nearby tissues and leukemia The 1986 Chernobyl nuclear accident contaminated about 30 000 km2 with greater than 10 kBq m2 with 90Sr which accounts for about 5 of the 90Sr which was in the reactor core HistoryFlame test for strontium Strontium is named after the Scottish village of Strontian Scottish Gaelic Sron an t Sithein where it was discovered in the ores of the lead mines In 1790 Adair Crawford a physician engaged in the preparation of barium and his colleague William Cruickshank recognised that the Strontian ores exhibited properties that differed from those in other heavy spars sources This allowed Crawford to conclude on page 355 it is probable indeed that the scotch mineral is a new species of earth which has not hitherto been sufficiently examined The physician and mineral collector Friedrich Gabriel Sulzer analysed together with Johann Friedrich Blumenbach the mineral from Strontian and named it strontianite He also came to the conclusion that it was distinct from the witherite and contained a new earth neue Grunderde In 1793 Thomas Charles Hope a professor of chemistry at the University of Glasgow studied the mineral and proposed the name strontites He confirmed the earlier work of Crawford and recounted Considering it a peculiar earth I thought it necessary to give it an name I have called it Strontites from the place it was found a mode of derivation in my opinion fully as proper as any quality it may possess which is the present fashion The element was eventually isolated by Sir Humphry Davy in 1808 by the electrolysis of a mixture containing strontium chloride and mercuric oxide and announced by him in a lecture to the Royal Society on 30 June 1808 In keeping with the naming of the other alkaline earths he changed the name to strontium The first large scale application of strontium was in the production of sugar from sugar beet Although a crystallisation process using strontium hydroxide was patented by Augustin Pierre Dubrunfaut in 1849 the large scale introduction came with the improvement of the process in the early 1870s The German sugar industry used the process well into the 20th century Before World War I the beet sugar industry used 100 000 to 150 000 tons of strontium hydroxide for this process per year The strontium hydroxide was recycled in the process but the demand to substitute losses during production was high enough to create a significant demand initiating mining of strontianite in the Munsterland The mining of strontianite in Germany ended when mining of the celestine deposits in Gloucestershire started These mines supplied most of the world strontium supply from 1884 to 1941 Although the celestine deposits in the Granada basin were known for some time the large scale mining did not start before the 1950s During atmospheric nuclear weapons testing it was observed that strontium 90 is one of the nuclear fission products with a relatively high yield The similarity to calcium and the chance that the strontium 90 might become enriched in bones made research on the metabolism of strontium an important topic OccurrenceSee also Category Strontium minerals The mineral celestine SrSO4 Strontium commonly occurs in nature being the 15th most abundant element on Earth its heavier congener barium being the 14th estimated to average approximately 360 parts per million in the Earth s crust and is found chiefly as the sulfate mineral celestine SrSO4 and the carbonate strontianite SrCO3 Of the two celestine occurs much more frequently in deposits of sufficient size for mining Because strontium is used most often in the carbonate form strontianite would be the more useful of the two common minerals but few deposits have been discovered that are suitable for development Because of the way it reacts with air and water strontium only exists in nature when combined to form minerals Naturally occurring strontium is stable but its synthetic isotope Sr 90 is only produced by nuclear fallout In groundwater strontium behaves chemically much like calcium At intermediate to acidic pH Sr2 is the dominant strontium species In the presence of calcium ions strontium commonly forms coprecipitates with calcium minerals such as calcite and anhydrite at an increased pH At intermediate to acidic pH dissolved strontium is bound to soil particles by cation exchange The mean strontium content of ocean water is 8 mg L At a concentration between 82 and 90 mmol L of strontium the concentration is considerably lower than the calcium concentration which is normally between 9 6 and 11 6 mmol L It is nevertheless much higher than that of barium 13 mg L ProductionThe major producers of strontium as celestine as of January 2024 are Spain 200 000 t Iran 200 000 t China 80 000 t Mexico 35 000 t and Argentina 700 t Although strontium deposits occur widely in the United States they have not been mined since 1959 A large proportion of mined celestine SrSO4 is converted to the carbonate by two processes Either the celestine is directly leached with sodium carbonate solution or the celestine is roasted with coal to form the sulfide The second stage produces a dark coloured material containing mostly strontium sulfide This so called black ash is dissolved in water and filtered Strontium carbonate is precipitated from the strontium sulfide solution by introduction of carbon dioxide The sulfate is reduced to the sulfide by the carbothermic reduction SrSO4 2 C SrS 2 CO2 About 300 000 tons are processed in this way annually The metal is produced commercially by reducing strontium oxide with aluminium The strontium is distilled from the mixture Strontium metal can also be prepared on a small scale by electrolysis of a solution of strontium chloride in molten potassium chloride Sr2 2 e Sr 2 Cl Cl2 2 e ApplicationsMost of the world s production of strontium used to be consumed in the production of cathode ray tube CRT displays The glass contained strontium and barium oxide to block X rays Consuming 75 of production the primary use for strontium was in glass for colour television cathode ray tubes where it prevented X ray emission This application for strontium has been declining because CRTs are being replaced by other display methods This decline has a significant influence on the mining and refining of strontium All parts of the CRT must absorb X rays In the neck and the funnel of the tube lead glass is used for this purpose but this type of glass shows a browning effect due to the interaction of the X rays with the glass Therefore the front panel is made from a different glass mixture with strontium and barium to absorb the X rays The average values for the glass mixture determined for a recycling study in 2005 is 8 5 strontium oxide and 10 barium oxide Because strontium is so similar to calcium it is incorporated in the bone All four stable isotopes are incorporated in roughly the same proportions they are found in nature However the actual distribution of the isotopes tends to vary greatly from one geographical location to another Thus analyzing the bone of an individual can help determine the region it came from This approach helps to identify the ancient migration patterns and the origin of commingled human remains in battlefield burial sites 87Sr 86Sr ratios are commonly used to determine the likely provenance areas of sediment in natural systems especially in marine and fluvial environments Dasch 1969 showed that surface sediments of Atlantic displayed 87Sr 86Sr ratios that could be regarded as bulk averages of the 87Sr 86Sr ratios of geological terrains from adjacent landmasses A good example of a fluvial marine system to which Sr isotope provenance studies have been successfully employed is the River Nile Mediterranean system Due to the differing ages of the rocks that constitute the majority of the Blue and White Nile catchment areas of the changing provenance of sediment reaching the River Nile Delta and East Mediterranean Sea can be discerned through strontium isotopic studies Such changes are climatically controlled in the Late Quaternary More recently 87Sr 86Sr ratios have also been used to determine the source of ancient archaeological materials such as timbers and corn in Chaco Canyon New Mexico 87Sr 86Sr ratios in teeth may also be used to track animal migrations Strontium aluminate is frequently used in glow in the dark toys as it is chemically and biologically inert Strontium salts are added to fireworks in order to create red colors Strontium carbonate and other strontium salts are added to fireworks to give a deep red colour This same effect identifies strontium cations in the flame test Fireworks consume about 5 of the world s production Strontium carbonate is used in the manufacturing of hard ferrite magnets Strontium chloride is sometimes used in toothpastes for sensitive teeth One popular brand includes 10 total strontium chloride hexahydrate by weight Small amounts are used in the refining of zinc to remove small amounts of lead impurities The metal itself has a limited use as a getter to remove unwanted gases in vacuums by reacting with them although barium may also be used for this purpose The ultra narrow optical transition between the Kr 5s21S0 electronic ground state and the metastable Kr 5s5p 3P0 excited state of 87Sr is one of the leading candidates for the future re definition of the second in terms of an optical transition as opposed to the current definition derived from a microwave transition between different hyperfine ground states of 133Cs Current optical atomic clocks operating on this transition already surpass the precision and accuracy of the current definition of the second Radioactive strontium RTGs from Soviet era lighthouses 89Sr is the active ingredient in Metastron a radiopharmaceutical used for bone pain secondary to metastatic bone cancer The strontium is processed like calcium by the body preferentially incorporating it into bone at sites of increased osteogenesis This localization focuses the radiation exposure on the cancerous lesion 90Sr has been used as a power source for radioisotope thermoelectric generators RTGs 90Sr produces approximately 0 93 watts of heat per gram it is lower for the form of 90Sr used in RTGs which is strontium fluoride However 90Sr has one third the lifetime and a lower density than 238Pu another RTG fuel The main advantage of 90Sr is that it is significantly cheaper than 238Pu and is found in nuclear waste The latter must be prepared by irradiating 237Np with neutrons then separating the modest amounts of 238Pu The principal disadvantage of 90Sr is the high energy beta particles produce Bremsstrahlung as they encounter nuclei of other nearby heavy atoms such as adjacent strontium This is mostly in the range of X rays Thus strong beta emitters also emit significant secondary X rays in most cases This requires significant shielding measures which complicates the design of RTGs using 90Sr The Soviet Union deployed nearly 1000 of these RTGs on its northern coast as a power source for lighthouses and meteorology stations Biological roleStrontium HazardsGHS labelling PictogramsSignal word DangerHazard statements H261 H315Precautionary statements P223 P231 P232 P370 P378 P422NFPA 704 fire diamond 202W Acantharea a relatively large group of marine radiolarian protozoa produce intricate mineral skeletons composed of strontium sulfate In biological systems calcium is substituted to a small extent by strontium In the human body most of the absorbed strontium is deposited in the bones The ratio of strontium to calcium in human bones is between 1 1000 and 1 2000 roughly in the same range as in the blood serum Effect on the human body The human body absorbs strontium as if it were its lighter congener calcium Because the elements are chemically very similar stable strontium isotopes do not pose a significant health threat The average human has an intake of about two milligrams of strontium a day In adults strontium consumed tends to attach only to the surface of bones but in children strontium can replace calcium in the mineral of the growing bones and thus lead to bone growth problems The biological half life of strontium in humans has variously been reported as from 14 to 600 days 1 000 days 18 years 30 years and at an upper limit 49 years The wide ranging published biological half life figures are explained by strontium s complex metabolism within the body However by averaging all excretion paths the overall biological half life is estimated to be about 18 years The elimination rate of strontium is strongly affected by age and sex due to differences in bone metabolism The drug strontium ranelate aids bone growth increases bone density and lessens the incidence of vertebral peripheral and hip fractures However strontium ranelate also increases the risk of venous thromboembolism pulmonary embolism and serious cardiovascular disorders including myocardial infarction Its use is therefore now restricted Its beneficial effects are also questionable since the increased bone density is partially caused by the increased density of strontium over the calcium which it replaces Strontium also bioaccumulates in the body Despite restrictions on strontium ranelate strontium is still contained in some supplements There is not much scientific evidence on risks of strontium chloride when taken by mouth Those with a personal or family history of blood clotting disorders are advised to avoid strontium Strontium has been shown to inhibit sensory irritation when applied topically to the skin Topically applied strontium has been shown to accelerate the recovery rate of the epidermal permeability barrier skin barrier Nuclear wasteStrontium 90 is a radioactive fission product produced by nuclear reactors used in nuclear power It is a major component of high level radioactivity of nuclear waste and spent nuclear fuel Its 29 year half life is short enough that its decay heat has been used to power arctic lighthouses but long enough that it can take hundreds of years to decay to safe levels Exposure from contaminated water and food may increase the risk of leukemia bone cancer and primary hyperparathyroidism Remediation Algae has shown selectivity for strontium in studies where most plants used in bioremediation have not shown selectivity between calcium and strontium often becoming saturated with calcium which is greater in quantity and also present in nuclear waste Researchers have looked at the bioaccumulation of strontium by Scenedesmus spinosus algae in simulated wastewater The study claims a highly selective biosorption capacity for strontium of S spinosus suggesting that it may be appropriate for use in treating nuclear wastewater A study of the pond alga Closterium moniliferum using non radioactive strontium found that varying the ratio of barium to strontium in water improved strontium selectivity See alsoPortal ChemistryReferencesGreenwood and Earnshaw p 112 Standard Atomic Weights Strontium CIAAW 1969 Prohaska Thomas Irrgeher Johanna Benefield Jacqueline Bohlke John K Chesson Lesley A Coplen Tyler B Ding Tiping Dunn Philip J H Groning Manfred Holden Norman E Meijer Harro A J 4 May 2022 Standard atomic weights of the elements 2021 IUPAC Technical Report Pure and Applied Chemistry doi 10 1515 pac 2019 0603 ISSN 1365 3075 Periodic Table of Elements Strontium Sr EnvironmentalChemistry com environmentalchemistry com Retrieved 7 December 2022 Arblaster John W 2018 Selected Values of the Crystallographic Properties of Elements Materials Park Ohio ASM International ISBN 978 1 62708 155 9 Colarusso P Guo B Zhang K Q Bernath P F 1996 High Resolution Infrared Emission Spectrum of Strontium Monofluoride PDF J Molecular Spectroscopy 175 1 158 Bibcode 1996JMoSp 175 158C doi 10 1006 jmsp 1996 0019 Weast Robert 1984 CRC Handbook of Chemistry and Physics Boca Raton Florida Chemical Rubber Company Publishing pp E110 ISBN 0 8493 0464 4 Kondev F G Wang M Huang W J Naimi S Audi G 2021 The NUBASE2020 evaluation of nuclear properties PDF Chinese Physics C 45 3 030001 doi 10 1088 1674 1137 abddae Mineral Resource of the Month Strontium U S Geological Survey 8 December 2014 Retrieved 16 August 2015 Greenwood and Earnshaw pp 112 13 C R Hammond The elements pp 4 35 in Lide D R ed 2005 CRC Handbook of Chemistry and Physics 86th ed Boca Raton Florida CRC Press ISBN 0 8493 0486 5 Greenwood and Earnshaw p 111 Greenwood and Earnshaw p 119 Greenwood and Earnshaw p 121 Greenwood and Earnshaw p 117 Greenwood and Earnshaw p 115 Greenwood and Earnshaw p 124 Miyoshi N Kamiura K Oka H Kita A Kuwata R Ikehara D Wada M 2004 The Barbier Type Alkylation of Aldehydes with Alkyl Halides in the Presence of Metallic Strontium Bulletin of the Chemical Society of Japan 77 2 341 doi 10 1246 bcsj 77 341 Miyoshi N Ikehara D Kohno T Matsui A Wada M 2005 The Chemistry of Alkylstrontium Halide Analogues Barbier type Alkylation of Imines with Alkyl Halides Chemistry Letters 34 6 760 doi 10 1246 cl 2005 760 Miyoshi N Matsuo T Wada M 2005 The Chemistry of Alkylstrontium Halide Analogues Part 2 Barbier Type Dialkylation of Esters with Alkyl Halides European Journal of Organic Chemistry 2005 20 4253 doi 10 1002 ejoc 200500484 Greenwood and Earnshaw pp 136 37 Greenwood and Earnshaw p 19 Halperin Edward C Perez Carlos A Brady Luther W 2008 Perez and Brady s principles and practice of radiation oncology Lippincott Williams amp Wilkins pp 1997 ISBN 978 0 7817 6369 1 Retrieved 19 July 2011 Bauman Glenn Charette Manya Reid Robert Sathya Jinka 2005 Radiopharmaceuticals for the palliation of painful bone metastases a systematic review Radiotherapy and Oncology 75 3 258 E1 258 E13 doi 10 1016 j radonc 2005 03 003 PMID 16299924 Strontium Radiation Protection US EPA EPA 24 April 2012 Retrieved 18 June 2012 Chernobyl Assessment of Radiological and Health Impact 2002 update Chapter I The site and accident sequence PDF OECD NEA 2002 Retrieved 3 June 2015 Murray W H 1977 The Companion Guide to the West Highlands of Scotland London Collins ISBN 978 0 00 211135 5 Crawford Adair 1790 On the medicinal properties of the muriated barytes Medical Communications 2 301 59 Sulzer Friedrich Gabriel Blumenbach Johann Friedrich 1791 Uber den Strontianit ein Schottisches Fossil das ebenfalls eine neue Grunderde zu enthalten scheint Bergmannisches Journal 433 36 Thomas Charles Hope MD FRSE FRS 1766 1844 School of Chemistry www chem ed ac uk 16 February 2024 Doyle W P Thomas Charles Hope MD FRSE FRS 1766 1844 The University of Edinburgh Archived from the original on 2 June 2013 Although Thomas C Hope had investigated strontium ores since 1791 his research was published in Hope Thomas Charles 1798 Account of a mineral from Strontian and of a particular species of earth which it contains Transactions of the Royal Society of Edinburgh 4 2 3 39 doi 10 1017 S0080456800030726 S2CID 251579302 Murray T 1993 Elementary Scots The Discovery of Strontium Scottish Medical Journal 38 6 188 89 doi 10 1177 003693309303800611 PMID 8146640 S2CID 20396691 Hope Thomas Charles 1794 Account of a mineral from Strontian and of a particular species of earth which it contains Transactions of the Royal Society of Edinburgh 3 2 141 49 doi 10 1017 S0080456800020275 S2CID 251579281 Davy H 1808 Electro chemical researches on the decomposition of the earths with observations on the metals obtained from the alkaline earths and on the amalgam procured from ammonia Philosophical Transactions of the Royal Society of London 98 333 70 Bibcode 1808RSPT 98 333D doi 10 1098 rstl 1808 0023 S2CID 96364168 Taylor Stuart 19 June 2008 Strontian gets set for anniversary Lochaber News Archived from the original on 13 January 2009 a href wiki Template Cite web title Template Cite web cite web a CS1 maint bot original URL status unknown link Weeks Mary Elvira 1932 The discovery of the elements X The alkaline earth metals and magnesium and cadmium Journal of Chemical Education 9 6 1046 57 Bibcode 1932JChEd 9 1046W doi 10 1021 ed009p1046 Partington J R 1942 The early history of strontium Annals of Science 5 2 157 doi 10 1080 00033794200201411 Partington J R 1951 The early history of strontium Part II Annals of Science 7 95 doi 10 1080 00033795100202211 Many other early investigators examined strontium ore among them 1 Martin Heinrich Klaproth Chemische Versuche uber die Strontianerde Chemical experiments on strontian ore Crell s Annalen September 1793 no ii pp 189 202 and Nachtrag zu den Versuchen uber die Strontianerde Addition to the Experiments on Strontian Ore Crell s Annalen February 1794 no i p 99 also 2 Kirwan Richard 1794 Experiments on a new earth found near Stronthian in Scotland The Transactions of the Royal Irish Academy 5 243 56 Fachgruppe Geschichte Der Chemie Gesellschaft Deutscher Chemiker 2005 Metalle in der Elektrochemie pp 158 62 Heriot T H P 2008 strontium saccharate process Manufacture of Sugar from the Cane and Beet Read Books ISBN 978 1 4437 2504 0 Bornchen Martin Der Strontianitbergbau im Munsterland Archived from the original on 11 December 2014 Retrieved 9 November 2010 Martin Josem Ortega Huertas Miguel Torres Ruiz Jose 1984 Genesis and evolution of strontium deposits of the granada basin Southeastern Spain Evidence of diagenetic replacement of a stromatolite belt Sedimentary Geology 39 3 4 281 Bibcode 1984SedG 39 281M doi 10 1016 0037 0738 84 90055 1 Chain Fission Yields iaea org Nordin B E 1968 Strontium Comes of Age British Medical Journal 1 5591 566 doi 10 1136 bmj 1 5591 566 PMC 1985251 Turekian K K Wedepohl K H 1961 Distribution of the elements in some major units of the Earth s crust Geological Society of America Bulletin 72 2 175 92 Bibcode 1961GSAB 72 175T doi 10 1130 0016 7606 1961 72 175 DOTEIS 2 0 CO 2 Ober Joyce A Mineral Commodity Summaries 2010 Strontium PDF United States Geological Survey Retrieved 14 May 2010 Heuel Fabianek B 2014 Partition Coefficients Kd for the Modelling of Transport Processes of Radionuclides in Groundwater PDF Berichte des Forschungszentrums Julich 4375 ISSN 0944 2952 Stringfield V T 1966 Strontium Artesian water in Tertiary limestone in the southeastern States Geological Survey Professional Paper United States Government Printing Office pp 138 39 Angino Ernest E Billings Gale K Andersen Neil 1966 Observed variations in the strontium concentration of sea water Chemical Geology 1 145 Bibcode 1966ChGeo 1 145A doi 10 1016 0009 2541 66 90013 1 Sun Y Sun M Lee T Nie B 2005 Influence of seawater Sr content on coral Sr Ca and Sr thermometry Coral Reefs 24 23 doi 10 1007 s00338 004 0467 x S2CID 31543482 Kogel Jessica Elzea Trivedi Nikhil C Barker James M 5 March 2006 Industrial Minerals amp Rocks Commodities Markets and Uses ISBN 978 0 87335 233 8 Mineral commodity summaries 2024 Report Mineral Commodity Summaries Reston VA U S Geological Survey January 2024 doi 10 3133 mcs2024 ISBN 978 1 4113 4544 7 Kemal Mevlut Arslan V Akar A Canbazoglu M 1996 Production of SrCO3 by black ash process Determination of reductive roasting parameters CRC Press p 401 ISBN 978 90 5410 829 0 MacMillan J Paul Park Jai Won Gerstenberg Rolf Wagner Heinz Kohler Karl and Wallbrecht Peter 2002 Strontium and Strontium Compounds in Ullmann s Encyclopedia of Industrial Chemistry Wiley VCH Weinheim doi 10 1002 14356007 a25 321 Cathode Ray Tube Glass To Glass Recycling PDF ICF Incorporated USEP Agency Archived from the original PDF on 19 December 2008 Retrieved 7 January 2012 Ober Joyce A Polyak Desiree E Mineral Yearbook 2007 Strontium PDF United States Geological Survey Retrieved 14 October 2008 Mear F Yot P Cambon M Ribes M 2006 The characterization of waste cathode ray tube glass Waste Management 26 12 1468 76 Bibcode 2006WaMan 26 1468M doi 10 1016 j wasman 2005 11 017 PMID 16427267 Price T Douglas Schoeninger Margaret J Armelagos George J 1985 Bone chemistry and past behavior an overview Journal of Human Evolution 14 5 419 47 Bibcode 1985JHumE 14 419P doi 10 1016 S0047 2484 85 80022 1 Steadman Luville T Brudevold Finn Smith Frank A 1958 Distribution of strontium in teeth from different geographic areas The Journal of the American Dental Association 57 3 340 44 doi 10 14219 jada archive 1958 0161 PMID 13575071 Schweissing Matthew Mike Grupe Gisela 2003 Stable strontium isotopes in human teeth and bone a key to migration events of the late Roman period in Bavaria Journal of Archaeological Science 30 11 1373 83 Bibcode 2003JArSc 30 1373S doi 10 1016 S0305 4403 03 00025 6 Dasch J 1969 Strontium isotopes in weathering profiles deep sea sediments and sedimentary rocks Geochimica et Cosmochimica Acta 33 12 1521 52 Bibcode 1969GeCoA 33 1521D doi 10 1016 0016 7037 69 90153 7 Krom M D Cliff R Eijsink L M Herut B Chester R 1999 The characterisation of Saharan dusts and Nile particulate matter in surface sediments from the Levantine basin using Sr isotopes Marine Geology 155 3 4 319 30 Bibcode 1999MGeol 155 319K doi 10 1016 S0025 3227 98 00130 3 Benson L Cordell L Vincent K Taylor H Stein J Farmer G amp Kiyoto F 2003 Ancient maize from Chacoan great houses where was it grown Proceedings of the National Academy of Sciences 100 22 13111 15 Bibcode 2003PNAS 10013111B doi 10 1073 pnas 2135068100 PMC 240753 PMID 14563925 English NB Betancourt JL Dean JS Quade J October 2001 Strontium isotopes reveal distant sources of architectural timber in Chaco Canyon New Mexico Proc Natl Acad Sci USA 98 21 11891 96 Bibcode 2001PNAS 9811891E doi 10 1073 pnas 211305498 PMC 59738 PMID 11572943 Barnett Johnson Rachel Grimes Churchill B Royer Chantell F Donohoe Christopher J 2007 Identifying the contribution of wild and hatchery Chinook salmon Oncorhynchus tshawytscha to the ocean fishery using otolith microstructure as natural tags Canadian Journal of Fisheries and Aquatic Sciences 64 12 1683 92 Bibcode 2007CJFAS 64 1683B doi 10 1139 F07 129 S2CID 54885632 Porder S Paytan A amp E A Hadly 2003 Mapping the origin of faunal assemblages using strontium isotopes Paleobiology 29 2 197 204 doi 10 1666 0094 8373 2003 029 lt 0197 MTOOFA gt 2 0 CO 2 S2CID 44206756 Van der Heggen David October 2022 Persistent Luminescence in Strontium Aluminate A Roadmap to a Brighter Future Advanced Functional Materials 32 52 doi 10 1002 adfm 202208809 hdl 1854 LU 01GJ1338HX6QQBT438E4QW442N S2CID 253347258 Retrieved 21 April 2023 Chemistry of Firework Colors How Fireworks Are Colored Chemistry about com 10 April 2012 Archived from the original on 13 May 2008 Retrieved 14 April 2012 Ferrite Permanent Magnets Arnold Magnetic Technologies Archived from the original on 14 May 2012 Retrieved 18 January 2014 Barium Carbonate Chemical Products Corporation Archived from the original on 6 October 2014 Retrieved 18 January 2014 Ghom 1 December 2005 Textbook of Oral Medicine Jaypee Brothers Medical Publishers p 885 ISBN 978 81 8061 431 6 permanent dead link Cartlidge Edwin 28 February 2018 With better atomic clocks scientists prepare to redefine the second Science AAAS Retrieved 10 February 2019 Recommended values of standard frequencies BIPM www bipm org Retrieved 21 May 2023 FDA ANDA Generic Drug Approvals Food and Drug Administration What are the fuels for radioisotope thermoelectric generators qrg northwestern edu Doyle James 30 June 2008 Nuclear safeguards security and nonproliferation achieving security with technology and policy Elsevier p 459 ISBN 978 0 7506 8673 0 O Brien R C Ambrosi R M Bannister N P Howe S D Atkinson H V 2008 Safe radioisotope thermoelectric generators and heat sources for space applications Journal of Nuclear Materials 377 3 506 21 Bibcode 2008JNuM 377 506O doi 10 1016 j jnucmat 2008 04 009 Strontium 343730 Sigma Aldrich De Deckker Patrick 2004 On the celestite secreting Acantharia and their effect on seawater strontium to calcium ratios Hydrobiologia 517 1 3 1 Bibcode 2004HyBio 517 1D doi 10 1023 B HYDR 0000027333 02017 50 S2CID 42526332 Pors Nielsen S 2004 The biological role of strontium Bone 35 3 583 88 doi 10 1016 j bone 2004 04 026 PMID 15336592 Cabrera Walter E Schrooten Iris De Broe Marc E d Haese Patrick C 1999 Strontium and Bone Journal of Bone and Mineral Research 14 5 661 68 doi 10 1359 jbmr 1999 14 5 661 PMID 10320513 S2CID 32627349 Emsley John 2011 Nature s building blocks an A Z guide to the elements Oxford University Press p 507 ISBN 978 0 19 960563 7 Agency for Toxic Substances and Disease Registry 26 March 2014 Strontium Public Health Statement ATSDR cdc gov Agency for Toxic Substances and Disease Registry Retrieved 12 January 2024 Tiller B L 2001 4 5 Fish and Wildlife Surveillance PDF Hanford Site 2001 Environmental Report DOE archived from the original PDF on 11 May 2013 retrieved 14 January 2014 Driver C J 1994 Ecotoxicity Literature Review of Selected Hanford Site Contaminants PDF DOE doi 10 2172 10136486 OSTI 10136486 retrieved 14 January 2014 Freshwater Ecology and Human Influence Area IV Envirothon Archived from the original on 1 January 2014 Retrieved 14 January 2014 Radioisotopes That May Impact Food Resources PDF Epidemiology Health and Social Services State of Alaska Archived from the original on 21 August 2014 Retrieved 14 January 2014 a href wiki Template Cite web title Template Cite web cite web a CS1 maint bot original URL status unknown link Human Health Fact Sheet Strontium PDF Argonne National Laboratory October 2001 Archived from the original PDF on 24 January 2014 Retrieved 14 January 2014 Biological Half life HyperPhysics Retrieved 14 January 2014 Glasstone Samuel Dolan Philip J 1977 XII Biological Effects PDF The effects of Nuclear Weapons p 605 Retrieved 14 January 2014 Shagina N B Bougrov N G Degteva M O Kozheurov V P Tolstykh E I 2006 An application of in vivo whole body counting technique for studying strontium metabolism and internal dose reconstruction for the Techa River population Journal of Physics Conference Series 41 1 433 40 Bibcode 2006JPhCS 41 433S doi 10 1088 1742 6596 41 1 048 S2CID 32732782 Meunier P J Roux C Seeman E Ortolani S Badurski J E Spector T D Cannata J Balogh A Lemmel E M Pors Nielsen S Rizzoli R Genant H K Reginster J Y January 2004 The effects of strontium ranelate on the risk of vertebral fracture in women with postmenopausal osteoporosis PDF New England Journal of Medicine 350 5 459 68 doi 10 1056 NEJMoa022436 hdl 2268 7937 PMID 14749454 Reginster JY Seeman E De Vernejoul MC Adami S Compston J Phenekos C Devogelaer J P Diaz Curiel M Sawicki A Goemaere S Sorensen O H Felsenberg D Meunier P J May 2005 Strontium ranelate reduces the risk of nonvertebral fractures in postmenopausal women with osteoporosis treatment of peripheral osteoporosis TROPOS study PDF The Journal of Clinical Endocrinology amp Metabolism 90 5 2816 22 doi 10 1210 jc 2004 1774 PMID 15728210 Strontium ranelate cardiovascular risk restricted indication and new monitoring requirements Medicines and Healthcare products Regulatory Agency UK March 2014 Price Charles T Langford Joshua R Liporace Frank A 5 April 2012 Essential Nutrients for Bone Health and a Review of their Availability in the Average North American Diet Open Orthop J 6 143 49 doi 10 2174 1874325001206010143 PMC 3330619 PMID 22523525 Strontium WebMD Retrieved 20 November 2017 Strontium for Osteoporosis WebMD Retrieved 20 November 2017 Hahn G S 1999 Strontium Is a Potent and Selective Inhibitor of Sensory Irritation PDF Dermatologic Surgery 25 9 689 94 doi 10 1046 j 1524 4725 1999 99099 x PMID 10491058 Archived from the original PDF on 31 May 2016 Hahn G S 2001 Anti irritants for Sensory Irritation Handbook of Cosmetic Science and Technology CRC Press p 285 ISBN 978 0 8247 0292 2 Kim Hyun Jeong Kim Min Jung Jeong Se Kyoo 2006 The Effects of Strontium Ions on Epidermal Permeability Barrier The Korean Dermatological Association Korean Journal of Dermatology 44 11 1309 Archived from the original on 4 June 2021 Retrieved 31 March 2014 Potera Carol 2011 HAZARDOUS WASTE Pond Algae Sequester Strontium 90 Environ Health Perspect 119 6 A244 doi 10 1289 ehp 119 a244 PMC 3114833 PMID 21628117 Boehm BO Rosinger S Belyi D Dietrich JW 18 August 2011 The parathyroid as a target for radiation damage The New England Journal of Medicine 365 7 676 8 doi 10 1056 NEJMc1104982 PMID 21848480 Liu Mingxue Dong Faqin Kang Wu Sun Shiyong Wei Hongfu Zhang Wei Nie Xiaoqin Guo Yuting Huang Ting Liu Yuanyuan 2014 Biosorption of Strontium from Simulated Nuclear Wastewater by Scenedesmus spinosus under Culture Conditions Adsorption and Bioaccumulation Processes and Models Int J Environ Res Public Health 11 6 6099 6118 doi 10 3390 ijerph110606099 PMC 4078568 PMID 24919131 BibliographyGreenwood Norman N Earnshaw Alan 1997 Chemistry of the Elements 2nd ed Butterworth Heinemann ISBN 978 0 08 037941 8 External linksStrontium at Wikipedia s sister projects Definitions from WiktionaryMedia from CommonsNews from WikinewsQuotations from WikiquoteTexts from WikisourceTextbooks from WikibooksResources from Wikiversity WebElements com Strontium Strontium at The Periodic Table of Videos University of Nottingham

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