aromatic compounds
Cards (26)
- Aromatic compoundsOrganic chemicals that include one or more ring of six carbon atoms with delocalised bonding
- Aliphatic compoundsStraight or branched chain organic substances
- BenzeneThe simplest aromatic compound, with the molecular formula C6H6
- Benzene's structure
- Six C atoms in a hexagonal ring, with one H atom bonded to each C atom
- Each C atom is bonded to two other C atoms and one H atom by single covalent σ-bonds, leaving one unused electron on each C atom in a p orbital, perpendicular to the plane of the ring
- The six p electrons are delocalised in a ring structure above and below the plane of carbon atoms
- Kekule's proposed structure for benzene, with alternate single and double covalent bonds, is not correct
- Evidence suggests all the C-C bonds in benzene are the same length and have a bond energy between a C-C single and C=C double bond</b>
- DelocalisationThe six electrons in the pi bonds are delocalised and spread out over the whole ring, not attached to a particular atom
- The H-C-C bond angle in benzene is 120°
- Delocalisation of electrons in benzeneBenzene is more thermodynamically stable than a non-delocalised structure
- Delocalisation energyThe increase in stability connected to delocalisation
- Naming aromatic compounds
- The simplest molecules are derivatives of benzene and have benzene at the root of the name
- If two or more substituents are present, their positions must be indicated by numbers to give the lowest possible numbers to the substituents
- When two or more different substituents are present, they are listed in alphabetical order and di, tri prefixes should be used
- Phenyl groupThe C6H5- group, which can be regarded as a substituent side group on another molecule
- Benzene does not generally undergo addition reactions as this would involve breaking up the delocalised system
- Most of benzene's reactions involve substituting one H for another atom or group of atoms, usually electrophilic substitutions
- Benzene vs alkenes in reaction with bromineBenzene does not react with bromine without additional halogen carrier chemicals, while alkenes react easily with bromine at room temperature
- Toxicity of benzeneBenzene is a carcinogen and is banned for use in schools, while methylbenzene is less toxic and reacts more readily
- Nitration of benzene1. Reaction with conc. nitric acid in the presence of conc. sulfuric acid catalyst2. Forms nitrobenzene via electrophilic substitution, with the NO2+ electrophile
- Halogenation of benzene1. Reaction with bromine or chlorine, using FeBr3 or AlCl3/FeCl3 catalyst2. Forms bromobenzene or chlorobenzene via electrophilic substitution, with the Br+ or Cl+ electrophile
- Friedel-Crafts alkylation1. Reaction of benzene with a chloroalkane, using anhydrous AlCl3 catalyst2. Forms an alkylbenzene via electrophilic substitution, with the R+ electrophile
- Friedel-Crafts acylation1. Reaction of benzene with an acyl chloride, using anhydrous AlCl3 catalyst2. Forms a phenyl ketone via electrophilic substitution, with the RCO+ electrophile
- PhenolsCompounds where the OH group is directly attached to the benzene ring
- Properties of phenols
- Phenols are very weakly acidic, weaker than carboxylic acids
- Phenols react with Na and NaOH, but not Na2CO3 like carboxylic acids
- Reaction of phenol with brominePhenol undergoes multiple substitution with bromine at room temperature, forming 2,4,6-tribromophenol
- Reaction of phenol with nitric acidPhenol reacts with 4M HNO3 at room temperature, forming 2-nitrophenol or 4-nitrophenol via electrophilic substitution
- Effect of side groups on substitutionElectron-donating groups like OH and NH2 direct further substitution to the 2- and 4-positions, while electron-withdrawing groups like NO2 have a 3-directing effect
- Effect of delocalisation on side groups with lone pairsDelocalisation extends to include the lone pairs on N, O and Cl, changing the properties and reactions of the side group