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Raschig–Hooker process

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The Raschig–Hooker process is a chemical process for the production of chlorobenzene and phenol.[1][2]

The Raschig–Hooker process was patented by Friedrich Raschig, a German chemist and politician also known for the Raschig process, the Olin Raschig process and the Raschig ring.[3] He first begun to use this reaction in 1891 in order to manufacture phenol.

Overview of the Raschig-Hooker process

The main steps in this process are the production of chlorobenzene from benzene, hydrochloric acid and oxygen, and the subsequent hydrolysis of chlorobenzene to phenol.[4] The first step uses either a copper or iron chloride catalyst and exposes the materials to air at 200–250 °C.[5][6][7][8] In the second step, the resulting chlorobenzene is introduced to steam at 450 °C over a silicon catalyst that hydrolyses the chlorobenzene, giving phenol and hydrogen chloride that can then be recycled back to the first step.[6][7] Due to the two step nature, the Raschig–Hooker process can be used to produce either chlorobenzene or phenol.

Reaction scheme of the Raschig-Hooker process

The Raschig–Hooker process's ability to make phenol makes it comparable to other methods, such as the Dow and Bayer process, which also converts benzene into phenol. In fact, the ability to recycle the hydrogen chloride made the Raschig–Hooker process preferable to the Dow and Bayer process, which requires its sodium chloride product to be converted into chlorine and sodium hydroxide. The reaction, however, takes place at very high temperatures in a very acidic environment with hydrogen chloride vapor and therefore the industrial setting must use highly corrosion resistant equipment for the reaction. While the Raschig–Hooker process does recycle the hydrogen chloride it produces, its catalyst experiences carbon deposition and must be frequently regenerated. The harsh chemical environment, use of catalysts, and large energy consumption has made it a target for green chemistry alternatives.[6]

The Raschig–Hooker process suffers from selectivity issues in both steps. In the first step, the reaction is only run to 10% to 15% conversion to prevent the second addition of a chlorine atom to the desired chlorobenzene. Despite this, the overall selectivity of the reaction is 70% to 85%. This second addition can be reversed using the Hooker modification, though it is also costly. The second step shares the low conversion rate and high selectivity of the first step. The small amount conversion per reaction offsets the monetary benefit of recycling the hydrogen chloride due to the large initial cost of the reaction. Therefore, the Raschig–Hooker process needed to be run at high concentrations in large reactors to be industrially economical.[6]

Due to its low productivity, this process is largely unused today. As of 1997, every plant in the United States that was using the Raschig–Hooker process has been shut down, though it was still used by some plants in countries such as Argentina, India, Italy, and Poland. Rather than using the Raschig–Hooker process, some companies use the Hock or cumene process, which instead synthesizes acetone and phenol from benzene and propylene. This preferred process has dominated the market, especially as acetone is also a highly desired substance.[6]

References

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  1. ^ Weber, Manfred; Weber, Markus; Kleine-Boymann, Michael (2004). "Phenol". Ullmann's Encyclopedia of Industrial Chemistry. doi:10.1002/14356007.a19_299.pub2. ISBN 3527306730.
  2. ^ Kropf, H. (1964). "Moderne technische Phenol-Synthesen I". Chemie Ingenieur Technik. 36 (7): 759–768. doi:10.1002/cite.330360707.
  3. ^ "Dr. Friedrich Raschig Obituary" (PDF). Nature. 121 (3048): 506. March 1928. doi:10.1038/121506c0.
  4. ^ Lidner, G; Nyberg, K (2012-12-06). Environmental Engineering: A Chemical Engineering Discipline. Springer. p. 37. ISBN 9789401026086.
  5. ^ Losch, P; Kolb, J.F.; Astafan, A; Daou, T.J.; Pinard, L; Pale, P; Louis, B (2016). "Eco-compatible zeolite-catalysed continuous halogenation of aromatics". Green Chemistry. 18 (17): 4714–4724. doi:10.1039/C6GC00731G.
  6. ^ a b c d e Weissermel, Klaus; Arpe, Hans-Jrgen, eds. (2003-05-27), "Benzene Derivatives", Industrial Organic Chemistry, Weinheim, Germany: Wiley-VCH Verlag GmbH, pp. 351–352, doi:10.1002/9783527619191.ch13, ISBN 978-3-527-61919-1, retrieved 2022-12-20
  7. ^ a b Wittcoff, Harold; Reuben, Bryan; Plotkin, Jeffrey (2012-12-10). Industrial Organic Chemicals. John Wiley & Sons. p. 327. ISBN 9781280556692.
  8. ^ Tyman, J.H.P. (1996-08-21). Synthetic and Natural Phenols. Elsevier. p. 7. ISBN 9780080542195.