Air sensitivity explained

Air sensitivity is a term used, particularly in chemistry, to denote the reactivity of chemical compounds with some constituent of air. Most often, reactions occur with atmospheric oxygen (O₂) or water vapor (H₂O),^[1] although reactions with the other constituents of air such as carbon monoxide (CO), carbon dioxide (CO₂), and nitrogen (N₂) are also possible.^[2]

Method

A variety of air-free techniques have been developed to handle air-sensitive compounds. Two main types of equipment are gloveboxes and Schlenk lines.^[3] Glove boxes are sealed cabinets filled with an inert gas such as argon or nitrogen.^[4] Normal laboratory equipment can be set up in the glovebox, and manipulated by the use of gloves that penetrate its walls.^[5] The atmosphere can be regulated to approximately atmospheric pressure and set to be pure nitrogen or other gas with which the chemicals will not react.^[6] Chemicals and equipment can be transferred in and out via an airlock.^[7]

A Schlenk line is a vacuum and inert-gas dual-manifold that allows glassware to be evacuated and refilled with inert gas specially developed to work with air sensitive compounds. It is connected with a cold trap to prevent vapors from contaminating a rotary vane pump.^[8] The technique is modified from the double-tipped needle technique.^[9] These methods allow working in totally controlled and isolated environment.^[10]

Air-sensitive compounds

Air-sensitive compounds are substances that would react with components in air. Almost all metals react with air to form a thin passivating layer of oxide, which is often imperceptible.

Many bulk compounds react readily with air as well. The reactive components of air are . Very many compounds react with some or all of these species.^[11] Examples:

• O₂: organolithium compounds and Grignard reagents
• H₂O: anhydrous metal halides and acyl chlorides as well as organolithium compounds and Grignard reagents
• CO₂: strong bases such as sodium hydroxide, as well as organolithium compounds and Grignard reagents
• N₂: lithium metal (but not organolithium compounds)

Some semiconductors are air-sensitive.^[12]

See also

• Hygroscopy
  • Hydrophile Ultrahydrophobicity

Notes and References

1. http://www.sigmaaldrich.com/etc/medialib/flashapps/glassware-center/pdfs/al-techbull-al134.Par.0001.File.dat/al_techbull_al134.pdf Handling and Storage of Air-Sensitive Reagents
2. Web site: Techniques for handling air and moisture sensitivity. Dr. P. Wipf.
3. Book: W. Bouwkamp, Marco. working with air and moisture sensitive compounds. Stratingh Institute for Chemistry, University of Groningen. 2008. 4, 6.
4. http://www.ilpi.com/inorganic/glassware/glovebox.html Glove Boxes
5. Book: Wipf. Dr. P. techniques of handling air sensitivity compound. 30 August 2015.
6. News: Air Sensitive Sample Analysis Reduced Oxygen Moisture-Free Handling. Analysis of Carbon, Hydrogen, Nitrogen, Oxygen, and halogens including Fluorine. 2018-02-27. en-US.
7. Web site: Handling air‐sensitive compounds.
8. Web site: The Glassware Gallery: Schlenk Lines and Vacuum Lines. www.ilpi.com.
9. Smith Vosejpka . Laura J. . A simple and cost-effective technique for the transfer of air-sensitive solutions . Journal of Chemical Education . August 1993 . 70 . 8 . 665 . 10.1021/ed070p665.
10. Web site: Air-Sensitive Chemistry - Labware Sigma-Aldrich. Sigma-Aldrich. en.
11. Web site: Pyrophoric Control - FQE Chemicals. FQE Chemicals.
12. Web site: Application of Air-sensitive Semiconductors in Nanoelectronics. www.sciencenewsline.com. en.