Strontium chloride explained

Strontium chloride (SrCl₂) is a salt of strontium and chloride. It is a 'typical' salt, forming neutral aqueous solutions. As with all compounds of strontium, this salt emits a bright red colour in flame, and is commonly used in fireworks to that effect. Its properties are intermediate between those for barium chloride, which is more toxic, and calcium chloride.

Preparation

Strontium chloride can be prepared by treating aqueous strontium hydroxide or strontium carbonate with hydrochloric acid:

Crystallization from cold aqueous solution gives the hexahydrate, SrCl₂·6H₂O. Dehydration of this salt occurs in stages, commencing above . Full dehydration occurs at .^[1]

Structure

In the solid state, SrCl₂ adopts a fluorite structure.^{[2] [3]} In the vapour phase the SrCl₂ molecule is non-linear with a Cl-Sr-Cl angle of approximately 130°. This is an exception to VSEPR theory which would predict a linear structure. Ab initio calculations have been cited to propose that contributions from d orbitals in the shell below the valence shell are responsible.^[4] Another proposal is that polarisation of the electron core of the strontium atom causes a distortion of the core electron density that interacts with the Sr-Cl bonds.^[5]

Uses

Strontium chloride is a precursor to other compounds of strontium, such as yellow strontium chromate, strontium carbonate, and strontium sulfate. Exposure of aqueous solutions of strontium chloride to the sodium salt of the desired anion often leads to formation of the solid precipitate:^[6]

SrCl₂ + Na₂CrO₄ → SrCrO₄ + 2 NaCl

SrCl₂ + Na₂CO₃ → SrCO₃ + 2 NaCl

SrCl₂ + Na₂SO₄ → SrSO₄ + 2 NaCl

Strontium chloride is often used as a red colouring agent in pyrotechnics. It imparts a much more intense red colour to the flames than most alternatives. It is employed in small quantities in glass-making and metallurgy. The radioactive isotope strontium-89, used for the treatment of bone cancer, is usually administered in the form of strontium chloride. Seawater aquaria require small amounts of strontium chloride, which is consumed during the growth of certain plankton.

Dental care

SrCl₂ is useful in reducing tooth sensitivity by forming a barrier over microscopic tubules in the dentin containing nerve endings that have become exposed by gum recession. Known in the U.S. as Elecol and Sensodyne, these products are called "strontium chloride toothpastes", although most now use saltpeter (KNO₃) instead which works as an analgesic rather than a barrier.^[7]

Biological research

Brief strontium chloride exposure induces parthenogenetic activation of oocytes^[8] which is used in developmental biological research.

Ammonia storage

A commercial company is using a strontium chloride-based artificial solid called AdAmmine as a means to store ammonia at low pressure, mainly for use in NO_x emission reduction on Diesel vehicles. They claim that their patented material can also be made from some other salts, but they have chosen strontium chloride for mass production.^[9] Earlier company research also considered using the stored ammonia as a means to store synthetic ammonia fuel under the trademark HydrAmmine and the press name "hydrogen tablet", however, this aspect has not been commercialized.^[10] Their processes and materials are patented. Their early experiments used magnesium chloride, and is also mentioned in that article.

Soil testing

Strontium chloride is used with citric acid in soil testing as a universal extractant of plant nutrients.^[11]

Notes and References

1. Book: 10.1002/14356007.a25_321. Strontium and Strontium Compounds . Ullmann's Encyclopedia of Industrial Chemistry . 2000 . MacMillan . J. Paul . Park . Jai Won . Gerstenberg . Rolf . Wagner . Heinz . Köhler . Karl . Wallbrecht . Peter . 3527306730 .
2. Book: West, Anthony R.. Solid state chemistry and its applications. 8 January 2014. 978-1-118-67625-7. Second edition, student. Chichester, West Sussex, UK. 854761803.
3. Web site: Mark. H.. Tolksdorf. S.. 1925. Ueber das Beugungsvermoegen der Atome fuer Roentgenstrahlen.. 2020-10-10. www.crystallography.net. en.
4. [Ab initio]
5. "Ion model and equilibrium configuration of the gaseous alkaline-earth dihalides" Guido M. and Gigli G. J. Chem. Phys. 65, 1397 (1976);
6. Hydrometallurgy . 84 . 3–4 . 2006 . 239–246 . Dissolution kinetics of celestite (SrSO₄) in HCl solution with BaCl₂ . Salih . Aydoğan . Murat . Erdemoğlu . Ali . Aras . Gökhan . Uçar . Alper . Özkan . 10.1016/j.hydromet.2006.06.001 . 2006HydMe..84..239A .
7. Web site: Sensodyne . . 2008-09-05 . https://web.archive.org/web/20080918193411/http://www.sensodyne.co.uk/how_it_works.htm . 2008-09-18 . dead .
8. O'Neill GT, Rolfe LR, Kaufman MH. "Developmental potential and chromosome constitution of strontium-induced mouse parthenogenones" (1991) Mol. Reprod. Dev. 30:214-219
9. Web site: Amminex A/S . AdAmmine™ . 2013-06-12 . dead . https://web.archive.org/web/20130801102020/http://amminex.dk/technology/the-solid.aspx . 2013-08-01.
10. Tue Johannesen . 'Solidified' ammonia as an energy storage material for fuel cell applications . Amminex . 2006 Annual NH3 Fuel Conference, October 9 – 10, 2006, Golden, CO . 2022-11-16 . May 2012. Via NH3 Fuel Association website.
11. Simard . R. R. . Strontium Chloride-Citric Acid Extraction Evaluated as a Soil-Testing Procedure for Phosphorus . Soil Science Society of America Journal . 1 March 1991 . 55 . 2 . 414 . 10.2136/sssaj1991.03615995005500020021x. 1991SSASJ..55..414S .