Acrylic acid explained

Acrylic acid (IUPAC: prop-2-enoic acid) is an organic compound with the formula CH2=CHCOOH. It is the simplest unsaturated carboxylic acid, consisting of a vinyl group connected directly to a carboxylic acid terminus. This colorless liquid has a characteristic acrid or tart smell. It is miscible with water, alcohols, ethers, and chloroform. More than a million tons are produced annually.

History

The word "acrylic" was coined in 1843, for a chemical derivative of acrolein, an acrid-smelling oil derived from glycerol.

Production

Acrylic acid is produced by oxidation of propylene, which is a byproduct of the production of ethylene and gasoline:

2 CH2=CHCH3 + 3 O2 → 2 CH2=CHCO2H + 2 H2O

Historical methods

Because acrylic acid and its esters have long been valued commercially, many other methods have been developed. Most have been abandoned for economic or environmental reasons. An early method was the hydrocarboxylation of acetylene ("Reppe chemistry"):

This method requires nickel carbonyl, high pressures of carbon monoxide, and acetylene, which is relatively expensive compared to propylene.

Acrylic acid was once manufactured by the hydrolysis of acrylonitrile, a material derived from propene by ammoxidation, but this route was abandoned because it cogenerates ammonium side products, which must be disposed of. Other now abandoned precursors to acrylic acid include ethenone and ethylene cyanohydrin.

Research

Carboxylating ethylene to acrylic acid under supercritical carbon dioxide is thermodynamically possible, but efficient catalysts have not been developed.[1] 3-Hydroxypropionic acid (3HP), an acrylic-acid precursor by dehydration, can be produced from sugars, but the process is not competitive.[2] [3]

Reactions and uses

Acrylic acid undergoes the typical reactions of a carboxylic acid. When reacted with an alcohol, it forms the corresponding ester. The esters and salts of acrylic acid are collectively known as acrylates (or propenoates). The most common alkyl esters of acrylic acid are methyl, butyl, ethyl, and 2-ethylhexyl acrylate.

Acrylic acid and its esters readily combine with themselves (to form polyacrylic acid) or other monomers (e.g. acrylamides, acrylonitrile, vinyl compounds, styrene, and butadiene) by reacting at their double bond, forming homopolymers or copolymers, which are used in the manufacture of various plastics, coatings, adhesives, elastomers, as well as floor polishes and paints.

Acrylic acid is used in many industries, including the diaper industry, the water treatment industry, and the textile industry. The annual worldwide consumption of acrylic acid is projected to reach more than an estimated 8,000 kilotons by 2020. This increase is expected due to its use in new applications, including personal care products, detergents, and products for adult incontinence.[4]

Substituents

As a substituent acrylic acid can be found as an acyl group or a carboxyalkyl group, depending on the removal of the group from the molecule.

More specifically, these are:

  1. The acryloyl group, with the removal of the −OH from carbon-1.
  2. The 2-carboxyethenyl group, with the removal of a −H from carbon-3. This substituent group is found in chlorophyll.

Safety

Acrylic acid is severely irritating and corrosive to the skin and the respiratory tract. Eye contact can result in severe and irreversible injury. Low exposure will cause minimal or no health effects, while high exposure could result in pulmonary edema. The is 340 mg/kg (rat, oral) with the lowest recorded being 293 mg/kg (oral, rat) comparable to ethylene glycol which is indicative of being a potent poison.[5] Ethyl acrylate was once used as synthetic food flavoring and was withdrawn by FDA possibly due to cancerogenic effects observed in lab animals.[6]

Animal studies showed that high-doses of acrylic acid decreased weight gain. Acrylic acid can be converted to non-toxic lactic acid.[7]

Acrylic acid is a constituent of tobacco smoke.[8]

See also

External links

Notes and References

  1. Sakakura . Toshiyasu . Choi . Jun-Chul . Yasuda . Hiroyuki . Transformation of Carbon dioxide . Chemical Reviews . 107 . 6 . 2365–2387 . 13 June 2007 . 10.1021/cr068357u . 17564481.
  2. http://www.durabilityanddesign.com/news/?fuseaction=view&id=5417 Sweet Deal: Dow and Partner Cook up Sugar-to-Acrylic Plan
  3. http://www.technologyreview.com/energy/26313/ Better Bugs to Make Plastics, Technology Review, September 20, 2010, retrieved January 9, 2012
  4. Web site: Acrylic acid market. 2018-05-30.
  5. Web site: Webwiser Acrylic Acid .
  6. Web site: Synthetic food flavorings law update .
  7. Web site: Provisional Peer-Reviewed Toxicity Values for Acrylic Acid. 2022-04-29 . www.google.com.
  8. Talhout. Reinskje. Schulz. Thomas. Florek. Ewa. Van Benthem. Jan. Wester. Piet. Opperhuizen. Antoon. Hazardous Compounds in Tobacco Smoke. International Journal of Environmental Research and Public Health. 8. 12. 2011. 613–628. 1660-4601. 10.3390/ijerph8020613. 21556207. 3084482. free.