Baeyer–Drewsen indigo synthesis
Organic reaction in which indigo is prepared from 2-nitrobenzaldehyde and acetone
The Baeyer–Drewsen indigo synthesis (1882) is an organic reaction in which indigo is prepared from 2-nitrobenzaldehyde and acetone[1][2] The reaction was developed by von Baeyer and Viggo Drewsen [da] in 1880 to produce the first synthetic indigo at laboratory scale. This procedure is not used at industrial scale.[3]
The reaction is classified as an aldol condensation. As a practical route to indigo, this method was displaced by routes from aniline.[4]
Mechanism
Note
In the English literature this reaction is sometimes called Baeyer–Drewson reaction, although the author of the original paper was spelled Drewsen.
References
- ^ Adolf Baeyer, Viggo Drewsen (1882). "Darstellung von Indigblau aus Orthonitrobenzaldehyd". Berichte der deutschen chemischen Gesellschaft. 15 (2): 2856–2864. doi:10.1002/cber.188201502274.
- ^ Helmut Schmidt (1997). "Indigo – 100 Jahre industrielle Synthese". Chemie in unserer Zeit. 31 (3): 121–128. doi:10.1002/ciuz.19970310304.
- ^ "Johannes Pfleger, Chemist". Evonik Industries. Archived from the original on 2014-05-24. Retrieved 2022-12-04.
- ^ Elmar Steingruber "Indigo and Indigo Colorants" Ullmann's Encyclopedia of Industrial Chemistry 2004, Wiley-VCH, Weinheim. doi:10.1002/14356007.a14_149.pub2
External links
- Lab Manual
- Lab-synthesis of indigo
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Topics in organic reactions
- Addition reaction
- Elimination reaction
- Polymerization
- Reagents
- Rearrangement reaction
- Redox reaction
- Regioselectivity
- Stereoselectivity
- Stereospecificity
- Substitution reaction
- A value
- Alpha effect
- Annulene
- Anomeric effect
- Antiaromaticity
- Aromatic ring current
- Aromaticity
- Baird's rule
- Baker–Nathan effect
- Baldwin's rules
- Bema Hapothle
- Beta-silicon effect
- Bicycloaromaticity
- Bredt's rule
- Bürgi–Dunitz angle
- Catalytic resonance theory
- Charge remote fragmentation
- Charge-transfer complex
- Clar's rule
- Conformational isomerism
- Conjugated system
- Conrotatory and disrotatory
- Curtin–Hammett principle
- Dynamic binding (chemistry)
- Edwards equation
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- Electromeric effect
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- Evelyn effect
- Flippin–Lodge angle
- Free-energy relationship
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- Hammett acidity function
- Hammett equation
- George S. Hammond
- Hammond's postulate
- Homoaromaticity
- Hückel's rule
- Hyperconjugation
- Inductive effect
- Kinetic isotope effect
- LFER solvent coefficients (data page)
- Marcus theory
- Markovnikov's rule
- Möbius aromaticity
- Möbius–Hückel concept
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- Negative hyperconjugation
- Neighbouring group participation
- 2-Norbornyl cation
- Nucleophile
- Kennedy J. P. Orton
- Passive binding
- Phosphaethynolate
- Polar effect
- Polyfluorene
- Ring strain
- Σ-aromaticity
- Spherical aromaticity
- Spiroaromaticity
- Steric effects
- Superaromaticity
- Swain–Lupton equation
- Taft equation
- Thorpe–Ingold effect
- Vinylogy
- Walsh diagram
- Woodward–Hoffmann rules
- Woodward's rules
- Y-aromaticity
- Yukawa–Tsuno equation
- Zaitsev's rule
- Σ-bishomoaromaticity