Thursday, July 18, 2019
Ch 18
Chapter 18 Ethers & Epoxides; Thiols and Sulfides Assigned Reading from McMurry: Read Sections 18. 1 through 18. 9; not responsible for ââ¬Å"Focus on â⬠¦ Epoxy Resins & Adhesives, pp. 697-698). Recommended Problems from McMurry: 18. 1a-e;18. 18. 2;18. 3a-d; 18. 4; 18. 5a-d; 18. 6a-b; 18. 7a-b; 18. 8; 18. 9; 18. 10; 18. 11; 18. 12a,b; 18. 13a,b; 18. 14a-c; 18. 16a-f; 18. 17; 18. 18; 18. 19a-c; 18. 20; 18. 21; 18. 22; 18. 23a-e; 18. 24a-I; 18. 25a-f; 18. 26a-d; 18. 27; 18. 28; 18. 29ad; 18. 30a-e; 18. 31; 18. 32; 18. 33; 18. 34; 18. 35a-d; 18. 36; 18. 37; 18. 38; 18. 39; 18. 40a,b; 18. 41a-d; 18. 2; 18. 43; 18. 44; 18. 45; 18. 45; 18. 46; 18. 47; 18. 48; 18. 49; 18. 51; 18. 52; 18. 53; 18. 54; 18. 551-e; 18. 56; 18. 57; 18. 58a-b; 18. 59a-b; 18. 60; 18. 61. 18. 1 Names and Properties of Ethers Method A: Simple ethers; alphabetize if two organic substituents. CH3ââ¬âCH2ââ¬âOââ¬âCH2ââ¬âCH3 Diethyl ether Methyl propyl ether O CH3ââ¬âCH2ââ¬âCH2ââ¬âOââ¬â CH3 CH3 Methyl phenyl ether SP 18. 01 Provide systematic names for the following ethers. CH3ââ¬âCH2ââ¬âOââ¬âCH2ââ¬âCH2ââ¬âCH2ââ¬âCH3 O SP 18. 02 Provide structures for the following systematic names. Systematic name: Isopropyl phenyl ether Systematic name: Cyclohexyl ethyl etherMethod B: Other functional groups present, ether component is an ââ¬Å"alkoxyâ⬠substituent. Alkoxy examples: methoxy -OCH3, ethoxy -OCH2CH3, propoxy -OCH2CH2CH3, etc. O C H3 O CH3 O C H3 para-Dimethoxybenzene 3-Methoxy-1-cyclopentene SP 18. 03 Provide systematic names for the following complex ethers. OCH3 O CH2CH3 Cl SP 18. 04 Provide structures for the following systematic names. Systematic name: meta-Bromopropoxybenzene Systematic name: 1-Isopropoxycyclopentene 18. 2 Synthesis of Ethers The Williamson Ether Synthesis R + O an alkoxide C X R SN2 an alkyl halide methyl & 1o best; X = Cl, Br, I, OTos O C ether productExample: O Na + Sodium phenoxide CH3 Br O CH3 Phenyl methyl e ther (anisole) + Na Br + X SP 18. 05 Complete the following reactions. CH3 CH3 C O Na + CH3 I + Na I CH3 CH3 CH3 C CH3 I + Na O CH3 + Na I SP 18. 06 Provide the suitable alkoxide and alkyl halide necessary to produce 2-ethoxy-2-methyl butane in good yield. CH3 CH3 CH2 C O CH3 CH2 CH3 + Na Br 8. 4 Oxymercuration Intermediates â⬠¢ For laboratory-scale hydration of an alkene â⬠¢ â⬠¢ Use mercuric acetate in THF followed by sodium borohydride Markovnikov orientation ââ¬â via mercurinium ion Alkoxymercuration of Alkenes General Reaction: R C C 2) NaBH4 H C R EtherAlkene RO Step #1 RO C 1) Hg(OAc)2, ROH H g OA c C C Step #2 R + HOAc Markovnikov addition SP 18. 07 Complete the following reactions by displaying the final major organic product. H C 1) Hg(OAc)2, CH3OH H C 2) NaBH4 H CH3 CH3 C C H CH3 1) Hg(OAc)2, CH3OH 2) NaBH4 SP 18. 08 Specify the alkene and alcohol needed to produce the following ether. Alcohol OCH2CH3 1) Hg(OAc)2, CH3 2) NaBH4 Alkene 18. 3 Reactions of Ethe rs: Acidic Ether Cleavage General Reaction: HX C O C C OH + X C (strong acid) Ether Alcohol Alkyl halide SP 18. 09 Predict the product for the following ether-cleavage reaction. CH3 CH3 C O CH3 HBr CH2CH3 8. 4 Reactions of Ethers: Claisen Rearrangement O OH 1,3 O to C shift Thermodynamically more stable o 250 Allyl phenyl ether C9H10O ortho-Allyl phenol C9H10O Mechanism (involves six-membered transition state): 1 O TS 2 3 1 O 2 H keto-enol tautomerization 3 O H SP 18. 10 Predict the structure for the following Claisen rearrangement. O o 250 2-Butenyl phenyl ether C10H12O 18. 5 Cyclic Ethers: Epoxides (2 methods) General Reaction 1: O C C + R Alkene C O O O O C H A peracid C An epoxide R C O A carboxylic acid Specific Example 1: O Cl C O O H m-CPBA o H O O + CH2Cl2, 25 C H 1,2-Epoxycycloheptane Cl H C O H 18. Cyclic Ethers: Epoxides (2 methods) General Reaction 2: C OH X2, H2O C C C X A halohydrin Alkene O NaOH H2O C + H2O + NaX C An epoxide Review Section 7. 3 Specific Example 2: H CH3 C C H CH3 cis-2-Butene Br2 H2O H CH3 Br C OH C H CH3 NaOH H2O O HC CH3 C H + H2O + NaBr CH3 meso-2,3-Dimethyl-oxirane (or cis-2,3-epoxybutane) SP 18. 11 Fill in the appropriate intermediates showing the correct stereochemistry. H CH3 C C CH3 Br2 NaOH H H2O H2O trans-2-Butene + H2O + NaBr 18. 6 Reactions of Epoxides: Ring-Opening General epoxide structure: O C Since each atom is sp3 there is considerable angle strain in the epoxide ring-system.C Acidic Conditions: Epoxide opening under acidic conditions (aqueous acid) yields 1,2-diols General Reaction: H H O O C H C HO C H2O An epoxide C OH A 1,2-diol (glycol) H O C H C + O H H O C + C H O H H O H Specific Example (using symmetrical epoxide): H + H H3O OH H2O OH O H H trans-1,2-Cyclohexanediol SP 18. 12 Predict the correct structure of the product diol showing the correct stereochemistry. O H CH3 C C CH3 H trans-2,3-epoxybutane H3O+ H2O Note: Epoxide opening under anhydrous acidic conditions yields halohydrins. Specific Example ( 2à ° and 1à ° carbons): o 1 carbon o 2 carbon O CH3 H C C H H 1,2-EpoxypropaneOH HCl Et2O CH3 C Cl CH2 Cl + CH3 H 1-Chloro-2-propanol (90%) C CH2 OH H 2-Chloro-1-propanol (10%) SP 18. 13 Using the above model predict the major halohydrin. O H C H C HCl H Et2O O H C C H H HCl OH C Et2O H Cl CH2 Cl + C CH2 OH H Explanation: In cases where a 2à ° carbon and a 1à ° carbon form the epoxide ring, the major halohydrin product will be the one where the incipient alcohol is 2à ° and the halide is 1à °. Upon protonation of the epoxide oxygen the halide ion simple attacks the less-hindered 1à ° carbon with a greater frequency to give the major regioisomer. Specific Example (3à ° and 1à ° carbons): SP 18. 4 Using the above model predict the major halohydrin. Circle one. O C C H H HCl OH C Et2O + C H Cl Cl H C OH C H H Explanation: In cases where a 3à ° carbon and a 1à ° carbon form the epoxide ring, the major halohydrin product will be the one where the incipient alcohol is 1à ° and the halide is 3à °. Upon protonation of the epoxide oxygen the halogen attacks the more-stabilized (same as moresubstituted) carbon atom to give the major regioisomer described. Basic Conditions: Note: Nucleophile will always attack least-hindered position. Specific Example: o 3 carbon 1o carbon O CH3 CH3 C C H H OH NaOH H2O, ? CH3 C CH2 OH CH3 -Methyl-1,2-propanediol SP 18. 15 Predict the structure of the 1,2-diol from the following reaction. O C C H H NaOH H2O, ? Reaction with Grignard Reagents: O CH3 CH3 C C H H OH 1) CH3CH2MgBr, Et2O 2) (aq) NH4Cl CH3 C CH2 CH3 CH2 CH3 SP 18. 16 Predict the structure of the organic product from the following Grignardepoxide reaction. O H C C H H 1) CH3MgBr, Et2O 2) (aq) NH4Cl Reaction with a 1à ° amine: O H C OH CH2 H H2NCH2CH2CH3 C CH2 N CH2 CH2 H Reaction with a 2à ° amine: O H C OH H H3C CH2 + N H3C H C CH2 N CH3 CH3 CH3 SP 18. 17 Predict the structure of the epoxide and amine needed to generate the amino alcohol shown to the right.OH + C H3 C CH3 Epoxide Amine CH2 N H 18. 7 Crown Ethers â⬠¢ Large rings consisting of repeating (-OCH2CH2-) or similar units â⬠¢ Named as x-crown-y ââ¬â x is the total number of atoms in the ring ââ¬â y is the number of oxygen atoms ââ¬â 18-crown-6 ether: 18-membered ring containing 6 oxygen atoms â⬠¢ Central cavity is electronegative and attracts cations 18. 8 Thiols and Sulfides â⬠¢ Thiols (RSH), are sulfur analogues of alcohols ââ¬â Named with the suffix -thiol ââ¬â SH group is called ââ¬Å"mercapto groupâ⬠(ââ¬Å"capturer of mercuryâ⬠) Thiols: Formation and Reaction â⬠¢ From alkyl halides by displacement with a sulfur nucleophile such as ââ¬âSH The alkylthiol product can undergo further reaction with the alkyl halide to give a symmetrical sulfide, giving a poorer yield of the thiol Sulfides â⬠¢ Sulfides (RSR? ), are sulfur analogues of ethers ââ¬â Named by rules used for ethers, with sulfide in place of ether for simple c ompounds and alkylthio in place of alkoxy Using Thiourea to Form Alkylthiols â⬠¢ Thiols can undergo further reaction with the alkyl halide to give dialkyl sulfides â⬠¢ For a pure alkylthiol use thiourea (NH2(C=S)NH2) as the nucleophile â⬠¢ This gives an intermediate alkylisothiourea salt, which is hydrolyzed cleanly to the alkyl thiourea Oxidation of Thiols to Disulfides Reaction of an alkyl thiol (RSH) with bromine or iodine gives a disulfide (RSSR) â⬠¢ The thiol is oxidized in the process and the halogen is reduced Sulfides â⬠¢ Thiolates (RS? ) are formed by the reaction of a thiol with a base â⬠¢ Thiolates react with primary or secondary alkyl halide to give sulfides (RSRââ¬â¢) â⬠¢ Thiolates are excellent nucleophiles and react with many electrophiles Sulfides as Nucleophiles â⬠¢ Sulfur compounds are more nucleophilic than their oxygen-compound analogues ââ¬â 3p valence electrons (on S) are less tightly held than 2p electrons (on O) â⬠¢ Sulfides react with primary alkyl halides (SN2) to give rialkylsulfonium salts (R3S+) Oxidation of Sulfides â⬠¢ Sulfides are easily oxidized with H2O2 to the sulfoxide (R2SO) â⬠¢ Oxidation of a sulfoxide with a peroxyacid yields a sulfone (R2SO2) â⬠¢ Dimethyl sulfoxide (DMSO) is often used as a polar aprotic solvent 18. 9 Spectroscopy of Ethers â⬠¢ Infrared: Cââ¬âO single-bond stretching 1050 to 1150 cm? 1 overlaps many other absorptions. â⬠¢ Proton NMR: H on a C next to ether O is shifted downfield to ? 3. 4 to ? 4. 5 ââ¬â The 1H NMR spectrum of dipropyl ether shows this signal at ? 3. 4 ââ¬â In epoxides, these Hââ¬â¢s absorb at ? 2. 5 to ? 3. 5 in their 1H NMR spectra Carbon NMR: Cââ¬â¢s in ethers exhibit a downfield shift to ? 50 to ? 80 Letââ¬â¢s Work a Problem When 2-methyl-2,5-pentanediol is treated with sulfuric acid, dehydration occurs and 2,2dimethyltetrahydrofuran is formed. Suggest a mechanism for this reaction. Which of the two ox ygen atoms is most likely to be eliminated and why? Answer First, there is protonation of the 3? ââ¬âOH group, then a 3? carbocation is formed via loss of H2O. Then there is a nucleophilic attack of the carbocation by the 2nd ââ¬âOH group. The 3? OH group is the one eliminated in all likelihood because its removal involves the formation of the more stable 3? carbocation.
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