Calcium oxide explained

Calcium oxide (formula: CaO), commonly known as quicklime or burnt lime, is a widely used chemical compound. It is a white, caustic, alkaline, crystalline solid at room temperature. The broadly used term lime connotes calcium-containing inorganic compounds, in which carbonates, oxides, and hydroxides of calcium, silicon, magnesium, aluminium, and iron predominate. By contrast, quicklime specifically applies to the single compound calcium oxide. Calcium oxide that survives processing without reacting in building products, such as cement, is called free lime.[1]

Quicklime is relatively inexpensive. Both it and the chemical derivative calcium hydroxide (of which quicklime is the base anhydride) are important commodity chemicals.

Preparation

Calcium oxide is usually made by the thermal decomposition of materials, such as limestone or seashells, that contain calcium carbonate (CaCO3; mineral calcite) in a lime kiln. This is accomplished by heating the material to above 825C,[2] a process called calcination or lime-burning, to liberate a molecule of carbon dioxide (CO2), leaving quicklime behind. This is also one of the few chemical reactions known in prehistoric times.[3]

CaCO3(s) → CaO(s) + CO2(g)

The quicklime is not stable and, when cooled, will spontaneously react with CO2 from the air until, after enough time, it will be completely converted back to calcium carbonate unless slaked with water to set as lime plaster or lime mortar.

Annual worldwide production of quicklime is around 283 million tonnes. China is by far the world's largest producer, with a total of around 170 million tonnes per year. The United States is the next largest, with around 20 million tonnes per year.[4]

Approximately 1.8t of limestone is required per 1.0t of quicklime. Quicklime has a high affinity for water and is a more efficient desiccant than silica gel. The reaction of quicklime with water is associated with an increase in volume by a factor of at least 2.5.

Hydroxyapatite's free CaO content rises with increased calcination temperatures and longer times. It also pinpoints particular temperature cutoffs and durations that impact the production of CaO, offering information on how calcination parameters impact the composition of the material.

Uses

CaO (s) + H2O (l) Ca(OH)2 (aq) (ΔHr = −63.7kJ/mol of CaO)

As it hydrates, an exothermic reaction results and the solid puffs up. The hydrate can be reconverted to quicklime by removing the water by heating it to redness to reverse the hydration reaction. One litre of water combines with approximately of quicklime to give calcium hydroxide plus 3.54 MJ of energy. This process can be used to provide a convenient portable source of heat, as for on-the-spot food warming in a self-heating can, cooking, and heating water without open flames. Several companies sell cooking kits using this heating method.[6]

Weapon

In 80 BC, the Roman general Sertorius deployed choking clouds of caustic lime powder to defeat the Characitani of Hispania, who had taken refuge in inaccessible caves. A similar dust was used in China to quell an armed peasant revolt in 178 AD, when lime chariots equipped with bellows blew limestone powder into the crowds.

Quicklime is also thought to have been a component of Greek fire. Upon contact with water, quicklime would increase its temperature above 150C and ignite the fuel.[16]

David Hume, in his History of England, recounts that early in the reign of Henry III, the English Navy destroyed an invading French fleet by blinding the enemy fleet with quicklime.[17] Quicklime may have been used in medieval naval warfare – up to the use of "lime-mortars" to throw it at the enemy ships.[18]

Substitutes

Limestone is a substitute for lime in many applications, which include agriculture, fluxing, and sulfur removal. Limestone, which contains less reactive material, is slower to react and may have other disadvantages compared with lime, depending on the application; however, limestone is considerably less expensive than lime. Calcined gypsum is an alternative material in industrial plasters and mortars. Cement, cement kiln dust, fly ash, and lime kiln dust are potential substitutes for some construction uses of lime. Magnesium hydroxide is a substitute for lime in pH control, and magnesium oxide is a substitute for dolomitic lime as a flux in steelmaking.[19]

Safety

Because of vigorous reaction of quicklime with water, quicklime causes severe irritation when inhaled or placed in contact with moist skin or eyes. Inhalation may cause coughing, sneezing, and labored breathing. It may then evolve into burns with perforation of the nasal septum, abdominal pain, nausea and vomiting. Although quicklime is not considered a fire hazard, its reaction with water can release enough heat to ignite combustible materials.[20]

Mineral

Calcium oxide is also a separate mineral species (with the unit formula CaO), named 'Lime'.[21] [22] It has an isometric crystal system, and can form a solid solution series with monteponite. The crystal is brittle, pyrometamorphic, and is unstable in moist air, quickly turning into portlandite (Ca(OH)2).[23]

External links

Notes and References

  1. Web site: free lime . DictionaryOfConstruction.com . https://web.archive.org/web/20171209222951/http://www.dictionaryofconstruction.com/definition/free-lime.html . 2017-12-09 . dead.
  2. Merck Index of Chemicals and Drugs, 9th edition monograph 1650
  3. Web site: Lime throughout history Lhoist - Minerals and lime producer. Lhoist.com. 10 March 2022.
  4. Book: Miller, M. Michael. Lime. Minerals Yearbook. 43.13. U.S. Geological Survey. 2007.
  5. Collie, Robert L. "Solar heating system" issued May 11, 1976
  6. Web site: Gretton. Lel. Lime power for cooking - medieval pots to 21st century cans. Old & Interesting. 13 February 2018.
  7. Web site: Compound Summary for CID 14778 - Calcium Oxide . PubChem.
  8. Gray . Theodore . September 2007 . Limelight in the Limelight . Popular Science . 84 . 2009-03-31 . 2008-10-13 . https://web.archive.org/web/20081013235058/http://www.popsci.com/node/9652 . dead .
  9. News: Tel Aviv University. Neolithic man: The first lumberjack?. August 9, 2012 . 2023-02-02. phys.org. en.
  10. 10.1017/S006824540000006X. Neolithic Lime Plastered Floors in Drakaina Cave, Kephalonia Island, Western Greece: Evidence of the Significance of the Site. The Annual of the British School at Athens. 103. 27–41. 2011. Karkanas . P. . Stratouli . G. . 129562287.
  11. Connelly, Ashley Nicole (May 2012) Analysis and Interpretation of Neolithic Near Eastern Mortuary Rituals from a Community-Based Perspective . Baylor University Thesis, Texas
  12. Book: Walker. Thomas A. Thomas A. Walker. The Severn Tunnel Its Construction and Difficulties. 1888. Richard Bentley and Son. London. 92.
  13. Scientific and Industrial Notes. Manchester Times. 13 May 1882. 8. Manchester, England.
  14. US Patent 255042, 14 March 1882
  15. Schotsmans . Eline M.J. . Denton . John . Dekeirsschieter . Jessica . Ivaneanu . Tatiana . Leentjes . Sarah . Janaway . Rob C. . Wilson . Andrew S. . Effects of hydrated lime and quicklime on the decay of buried human remains using pig cadavers as human body analogues . Forensic Science International . April 2012 . 217 . 1–3 . 50–59 . 10.1016/j.forsciint.2011.09.025. 22030481 . 2268/107339 . free .
  16. Book: Chemical and biological warfare: a comprehensive survey for the concerned citizen. 128. Croddy, Eric . Springer. 2002. 0-387-95076-1.
  17. Book: History of England. I. David Hume. David Hume. 1756.
  18. Sayers, W. (2006). "The Use of Quicklime in Medieval Naval Warfare". The Mariner's Mirror. Volume 92. Issue 3. pp. 262–269.
  19. Web site: Lime. 96. Prd-wret.s3-us-west-2.amazonaws.com. 2022-03-10. 2021-12-19. https://web.archive.org/web/20211219004903/https://prd-wret.s3-us-west-2.amazonaws.com/assets/palladium/production/atoms/files/mcs-2019-lime.pdf. dead.
  20. Web site: Hazards . usurped . https://web.archive.org/web/20120501110853/http://hazard.com/msds/mf/baker/baker/files/c0462.htm . May 1, 2012 . 2023-02-02. ww25.hazard.com. December 8, 1996 . Mallinckrodt Baker Inc. - Strategic Services Division .
  21. Web site: List of Minerals. Ima-mineralogy.org. 21 March 2011.
  22. Fiquet . G. . Richet . P. . Montagnac . G. . High-temperature thermal expansion of lime, periclase, corundum and spinel . Physics and Chemistry of Minerals . Dec 1999 . 27 . 2 . 103–111 . 10.1007/s002690050246 . 1999PCM....27..103F . 93706828 . 9 February 2023.
  23. Tian, Lin, Yan . X. K., S. C., J., & Zhao, C. Y. . 2022 . Lime . 10 March 2022 . Mindat.org. 10.1016/j.cej.2021.131229 .