Carbylamine reaction
Method of synthesizing an isocyanide
The carbylamine reaction (also known as the Hoffmann isocyanide synthesis) is the synthesis of an isocyanide by the reaction of a primary amine, chloroform, and base. The conversion involves the intermediacy of dichlorocarbene.
Illustrative is the synthesis of tert-butyl isocyanide from tert-butylamine in the presence of catalytic amount of the phase transfer catalyst benzyltriethylammonium chloride.[1]
- Me3CNH2 + CHCl3 + 3 NaOH → Me3CNC + 3 NaCl + 3 H2O
Similar reactions have been reported for aniline. It is used to prepare secondary amines.
Test for primary amines
As it is only effective for primary amines, the carbylamine reaction can be used as a chemical test for their presence. In this context, the reaction is also known as Saytzeff's isocyanide test.[2] In this reaction, the analyte is heated with alcoholic potassium hydroxide and chloroform. If a primary amine is present, the isocyanide (carbylamine) is formed, as indicated by a foul odour. The carbylamine test does not give a positive reaction with secondary and tertiary amines.
Mechanism
The mechanism involves the addition of amine to dichlorocarbene, a reactive intermediate generated by the dehydrohalogenation of chloroform. Two successive base-mediated dehydrochlorination steps result in formation of the isocyanide.
See also
- Isodiazomethane
- Carbene
References
- v
- t
- e
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
- Effective molarity
- Electromeric effect
- Electron-rich
- Electron-withdrawing group
- Electronic effect
- Electrophile
- Evelyn effect
- Flippin–Lodge angle
- Free-energy relationship
- Grunwald–Winstein equation
- 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
- More O'Ferrall–Jencks plot
- 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
