Some Important Reactions of Alcohols 1. Dehydration = loss of H 2 O to form an alkene 2. Oxidation = loss of H to fo

Some Important Reactions of Alcohols 1. Dehydration = loss of H2O to form an alkene 2. Oxidation = loss of H to form a C=O compound

Dehydration Examples CH3CHCH3 CH2=CHCH3 + H2O OH 2-propanol --> propene + water general pattern: alcohol --> alkene + water

Another example H H H OH H2O + cyclopentanol --> cyclopentene + water

How does reaction occur? * Loss of water from alcohol alone has high activation energy = alcohols dehydrate very, very, very slowly by themselves * speed up reaction by lowering Eact with catalyst

Catalyst for dehydration of alcohol is usually acid = H+ from H2SO4 (sulfuric acid) or enzyme in living organism.

Main thing to focus on: C-C C-C H+ H + H O O H H H lose H+& H2O C=C forms between C bonded to OH and adjacent C bonded to H lost as H+ C=C alkene

When the C-O bonds breaks to lose H2O, an adjacent C-H bond breaks to lose H+. The result is formation of the new pi (p) bond to make the alkene. Catalyst helps OH leave as H2O from alcohol.

When there is more than one kind of H on the C next to C-OH, more than one alkene can form: CH3CHCH2CH3 H2O + H+ heat OH CH2=CHCH2CH3 + CH3CH=CHCH3

Oxidation Reaction Examples CH3CH2-CH-CH3 OH [O] 2° alcohol O oxidizing agent CH3CH2-C-CH3 ketone

General reaction: R-CH-R’ R-C-R’ O OH [O] 2° ROH + [O] ---> ketone

Oxidizing agents remove H and e- from the grouping H-C-O-H that makes up the alcohol group to form C=O. Many reagents can do this: common ones are Cr or Mn compounds. Even household bleach (NaOCl) can be [O].

Primary alcohols can be oxidized in 2 stages: R-CH2-OH R-C-H O [O] aldehyde O O [O] R-C-H R-C-OH carboxylic acid

Aldehydes are easier to oxidize than 1° alcohols, so it is sometimes difficult to stop the reaction at the aldehyde stage. Special reagents have been developed to make it possible to get aldehydes by oxidizing a 1° alcohol.

Tertiary alcohols are not oxidized because there is no H on the C bonded to OH: R-C-O-H is 3° alcohol R CH3 R CH3-C-O-H no H on C CH3

Phenols are benzene compounds with an OH group attached to a sp2 C in ring: OH OH CO2H “phenol” salicylic acid

Phenols & Alcohols are not alike! * both have C-O-H * both form H-bonds, BUT: * alcohols are neutral compounds * phenols are acidic

ETHERS have the general formula R-O-R’ (has C-O-C bond) *bond angles about 109° *tetrahedral e- pairs on O *C-O-C shape is angular or bent

both Alkyl groups can be the same or different: CH3CH2-O-CH2CH3 “diethyl ether” is symmetrical CH3-O-CH2CH2CH3 “methyl propyl ether” is unsymmetrical

non-IUPAC names for ethers = “common names” name of alkyl group 1 (space) name of alkyl group 2 (space) ether see previous slide for examples

Ethers do not provide a H for a hydrogen bond, but can provide the electron pair of O. So: ethers are H-bond acceptors, they donate :O: to the H of another O-H or H-N

• • R O • H-O • R R’ ether H-bond acceptor alcohol H-bond donor

Sulfur Analogs of Alcohols and Ethers R-S-H thiol or mercaptan R-S-R’ thioether R-S-S-R’ disulfide Simply be able to recognize the type from structure.

Some Important Reactions of Alcohols 1. Dehydration = loss of H 2 O to form an alkene 2. Oxidation = loss of H to fo