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Transcript
Org. Chem I Handout #8 ALCOHOLS, ETHERS AND EXPOXIDES General Summary: • Alcohols and ethers are not good electrophiles (they do not contain a good leaving group). • Must convert the hydroxyl group (in alcohols) or the alkoxy group (in ethers) into a good leaving group before substitution or elimination will occur • Epoxides are strained three‐membered cyclic ethers that are very reactive towards strong nucleophiles and acids due to significant ring‐strain. Preparation of alcohols: General Reaction SN2 R X -OH + X- + R-OH Example SN2 CH3CH2Br -OH + CH3CH2OH * Works with methyl, 1o and sometimes 2o alkyl halides Preparation of ethers: General Reaction SN2 R1 X + -OR X- + R1-OR better to use alkyl halides with little or no sterics when you have a choice Example I NaH OH O- Na+ THF + O SN2 NaI alkoxide formation * Works with methyl, 1o and sometimes 2o alkyl halides Preparation of epoxides: General Reaction NaH HO Br "halohydrin" THF -O intramolecular Br O SN2 Copyright © Doug E. Frantz The University of Texas at San Antonio Org. Chem I Handout #8 Dehydration of alcohol to synthesize alkenes: via strong acids: strong acid with weak nucleophilic conjugate base C C H OH Reactivity order = 3o > 2o > 1o E1 pathway for 2o and 3o -carbocations are intermediates with rearrangments possible E2 pathway for 1o Zaitsev rule applies to product formation C C Ex. H2SO4, H3PO4 TsOH via POCl3: POCl3 E2 pathway predominates No carbocation rearrangments C C C C H OH N pyridine Synthesis of alkyl halides from alcohols: via strong acids: Reactivity order = 3o > 2o > 1o SN1 pathway for 2o and 3o -carbocations are intermediates with rearrangments possible SN2 pathway for 1o and CH3OH Need to use ZnCl2 for conversion of 1o ROH to R-Cl H-X C C H X C C H OH * this reaction is truthfully only useful for tertiary alcohols. For 1o and 2o alcohols, use the reagents below via specialized reagents: SOCl2 C C H OH pyridine C C H Cl Preferred method for methyl, 1o or 2o alcohols These occur via an SN2 pathway. PBr3 Make sure you know the mechanisms!!! C C H Br C C H OH Don’t forget about using tosylates in substitution and elimination reactions as well. In many cases, they are better than their halide counterparts. Reaction of ethers and epoxides: R1 O R2 + H-X (2 equiv) + R1 X R2 X X = Br or I Na+ -OCH3 true SN2 H3C H3C O + H2O Mechanism for each product depends on the nature of the alkyl group (i.e., 1o vs. 2o vs. 3o This reaction is not very useful synthetically HO HH H3C H3C H H CH3OH H3C H2SO4 H3CO OCH3 CH3 H OH H with strong Nu:, an SN2 attack occurs at the least sterically hindered carbon on the epoxide with strong acids (i.e., HCl), the mechanism is in between SN1 and SN2 and attack occurs at the more substituted carbon Copyright © Doug E. Frantz The University of Texas at San Antonio
