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14.5 Organolithium and Organomagnesium Compounds as bronsted Bases PROBLEM 14.3 Write the structure of the grignard reagent formed from each of the following compounds on reaction with magnesium in diethyl ether (a)p-Bromofluorobenzene (c)lodocyclobutane (b) Allyl chloride ( d) 1-Bromocyclohexene SAMPLE SOLUTION (a)Of the two halogen substituents on the aromatic ring , bromine reacts much faster than fluorine with magnesium. Therefore, fluorine is left intact on the ring while the carbon-bromine bond is converted to a car- bon-magnesium bond m+=.(M The formation of a grignard reagent is analogous to that of organolithium reagents except that each magnesium atom can participate in two separate one-electron transfer steps R:X:+ M →R:X于+Mg Alkyl halide Magnesium Anion radical Anion radical Halide Alkylmagnesium halide Organolithium and organomagnesium compounds find their chief use in the prepara- tion of alcohols by reaction with aldehydes and ketones. Before discussing these reactions, let us first examine the reactions of these organometallic compounds with proton donors. 14.5 ORGANOLITHIUM AND ORGANOMAGNESIUM COMPOUNDS AS BRONSTED BASES Organolithium and organomagnesium compounds are stable species when prepared in suitable solvents such as diethyl ether. They are strongly basic, however, and react instantly with proton donors even as weakly acidic as water and alcohols. a proton is ransferred from the hydroxyl group to the negatively polarized carbon of the organometallic compound to form a hydrocarbon →R一H+R'O:M+ CH3CH,CH2 CH,Li+ H,0- CH, CH,CH3 LIOH Butyllithium Butane(100%) Lithium hydroxide lgBr+CH3OH— t Ch,OMg Br Phenylmagnesium Methanol Benzene Methoxymagnesi (100%) Back Forward Main MenuToc Study Guide ToC Student o MHHE Website
PROBLEM 14.3 Write the structure of the Grignard reagent formed from each of the following compounds on reaction with magnesium in diethyl ether: (a) p-Bromofluorobenzene (c) Iodocyclobutane (b) Allyl chloride (d) 1-Bromocyclohexene SAMPLE SOLUTION (a) Of the two halogen substituents on the aromatic ring, bromine reacts much faster than fluorine with magnesium. Therefore, fluorine is left intact on the ring, while the carbon–bromine bond is converted to a carbon–magnesium bond. The formation of a Grignard reagent is analogous to that of organolithium reagents except that each magnesium atom can participate in two separate one-electron transfer steps: Organolithium and organomagnesium compounds find their chief use in the preparation of alcohols by reaction with aldehydes and ketones. Before discussing these reactions, let us first examine the reactions of these organometallic compounds with proton donors. 14.5 ORGANOLITHIUM AND ORGANOMAGNESIUM COMPOUNDS AS BRØNSTED BASES Organolithium and organomagnesium compounds are stable species when prepared in suitable solvents such as diethyl ether. They are strongly basic, however, and react instantly with proton donors even as weakly acidic as water and alcohols. A proton is transferred from the hydroxyl group to the negatively polarized carbon of the organometallic compound to form a hydrocarbon. H� � OR� �M �R R H R�O M CH3CH2CH2CH2Li Butyllithium H2O Water CH3CH2CH2CH3 Butane (100%) LiOH Lithium hydroxide MgBr Phenylmagnesium bromide CH3OH Methanol Benzene (100%) CH3OMgBr Methoxymagnesium bromide Magnesium Mg Mg Alkyl halide R X Anion radical [R ] X Alkyl radical R Halide ion X Anion radical [R ] X Alkylmagnesium halide Mg R X Mg F Br p-Bromofluorobenzene Mg Magnesium diethyl ether F MgBr p-Fluorophenylmagnesium bromide 14.5 Organolithium and Organomagnesium Compounds as Brønsted Bases 551 Back Forward Main Menu TOC Study Guide TOC Student OLC MHHE Website����������������������
CHAPTER FOURTEEN Organometallic Compounds Because of their basicity organolithium compounds and grignard reagents can not be prepared or used in the presence of any material that bears a hydroxyl group Nor are these reagents compatible with -NH or-SH groups, which can also con vert an organolithium or organomagnesium compound to a hydrocarbon by proton transter The carbon-metal bonds of organolithium and organomagnesium compounds have appreciable carbanionic character. Carbanions rank among the strongest bases that we'l see in this text. Their conjugate acids are hydrocarbons-very weak acids indeed. The quilibrium constants Ka for ionization of hydrocarbons are much smaller than the kas for water and alcohols Table 14.2 presents some approximate data for the acid strengths of representative hydro- Acidity increases in progressing from the top of Table 14.2 to the bottom. An acid will transfer a proton to the conjugate base of any acid above it in the table. Organo- act like carbanions and will abstract from any substance more acidic than a hydrocarbon. Thus, N-H groups and terminal alkynes(RC=C-H) are converted to their conjugate bases by proton transfer to organolithium and organomagnesium compounds TABLE 14.2 Approximate Acidities of Some Hydrocarbons and Reference Materials pk Conjugate base 2-Methylpropane (CH3)3C-H (CH3)3C Ethane CH3CH2--H CH3CH2 Methane HaC CH2=CH一H10 Benzene H-H 10-43 H H2N一H 10-36 Acetylene 10-26 cHCH2O一H10-16 16 CH3CH2O HO-H 18×10 15.7Ho *The acidic proton in each compound is shaded in red Back Forward Main MenuToc Study Guide ToC Student o MHHE Website
Because of their basicity organolithium compounds and Grignard reagents cannot be prepared or used in the presence of any material that bears a hydroxyl group. Nor are these reagents compatible with ±NH or ±SH groups, which can also convert an organolithium or organomagnesium compound to a hydrocarbon by proton transfer. The carbon–metal bonds of organolithium and organomagnesium compounds have appreciable carbanionic character. Carbanions rank among the strongest bases that we’ll see in this text. Their conjugate acids are hydrocarbons—very weak acids indeed. The equilibrium constants Ka for ionization of hydrocarbons are much smaller than the Ka’s for water and alcohols. Table 14.2 presents some approximate data for the acid strengths of representative hydrocarbons. Acidity increases in progressing from the top of Table 14.2 to the bottom. An acid will transfer a proton to the conjugate base of any acid above it in the table. Organolithium compounds and Grignard reagents act like carbanions and will abstract a proton from any substance more acidic than a hydrocarbon. Thus, N±H groups and terminal alkynes (RCPC±H) are converted to their conjugate bases by proton transfer to organolithium and organomagnesium compounds. C H Hydrocarbon (very weak acid) Proton H C Carbanion (very strong base) 552 CHAPTER FOURTEEN Organometallic Compounds TABLE 14.2 Approximate Acidities of Some Hydrocarbons and Reference Materials Compound 2-Methylpropane Ethane Methane Ethylene Benzene Ammonia Acetylene Ethanol Water 1071 1062 1060 1045 1043 1036 1026 1016 1.8 � 1016 Ka 71 62 60 45 43 36 26 16 15.7 Formula* pKa (CH3)3C±H CH3CH2±H CH3±H CH2œCH±H H2N±H HCPC±H CH3CH2O±H HO±H H H H H H H Conjugate base H H H H H (CH3)3C H3C HCPC H2N CH3CH2O HO CH3CH2 CH2œCH *The acidic proton in each compound is shaded in red. Back Forward Main Menu TOC Study Guide TOC Student OLC MHHE Website���������������������
14.6 Synthesis of Alcohols Using Grignard Reagents ChaLi+ CHa LiNH, Methyllithium Ammonia Methane Lithium amide (stronger base)(stronger acid (weaker acid:(weake Kn=10-3 Ka≈10 60 H2CH2MgBr+HC≡CH CH3 CH3 Ethylmagnesiu Acetylene Ethane Ethynylmagnesium bromide (stronger bas =( (weaker base PROBLEM 14.4 Butyllithium is commercially available and is frequently used by organic chemists as a strong base. Show how you could use butyllithium to pre pare solutions containing (a)Lithium diethylamide (CHa CH2)2NLi b) Lithium 1-hexanolate Cha(cH )4 CH oli (c) Lithium benzenethiolate, CsHsSLi SAMPLE SoLUTION When butyllithium is used as a base, it abstracts a proton, in this case a proton attached to nitrogen The source of lithium diethylamide must be diethylamine (CH3 CH2)2NH+ CH3 CH2 CH,Li ->(CH3 CH2) NLi CH3CH2 CH2 CH3 diethylamide (stronger acid (stronger base) (weaker base) (weaker acid) Although diethylamine is not specifically listed in Table 14.2, its strength as an acid (Ka ss 10)is, as might be expected, similar to that of ammonia It is sometimes necessary in a synthesis to reduce an alkyl halide to a hydrocar- bon. In such cases converting the halide to a grignard reagent and then adding water or an alcohol as a proton source is a satisfactory procedure. Adding DO to a grignard reagent is a commonly used method for introducing deuterium into a molecule at a spe- Deuterium is the mass 2 iso- cific location pe of hydrogen. Deute. CH3 CH=CHBr CHaCH=CHMgBr CHCHECHD times called"heavy water. Propenylmagnesium bromide I-Deuteriopropene(70%) 14.6 SYNTHESIS OF ALCOHOLS USING GRIGNARD REAGENTS The main synthetic application of Grignard reagents is their reaction with certain car bonyl-containing compounds to produce alcohols. Carbon-carbon bond formation is rapid and exothermic when a grignard reagent reacts with an aldehyde or ketone normally COMoX written as rMgX R—MgX A carbonyl group is quite polar, and its carbon atom is electrophilic. Grignard reagents are nucleophilic and add to carbonyl groups, forming a new carbon-carbon bond. This Back Forward Main MenuToc Study Guide ToC Student o MHHE Website
PROBLEM 14.4 Butyllithium is commercially available and is frequently used by organic chemists as a strong base. Show how you could use butyllithium to prepare solutions containing (a) Lithium diethylamide, (CH3CH2)2NLi (b) Lithium 1-hexanolate, CH3(CH2)4CH2OLi (c) Lithium benzenethiolate, C6H5SLi SAMPLE SOLUTION When butyllithium is used as a base, it abstracts a proton, in this case a proton attached to nitrogen. The source of lithium diethylamide must be diethylamine. Although diethylamine is not specifically listed in Table 14.2, its strength as an acid (Ka 1036) is, as might be expected, similar to that of ammonia. It is sometimes necessary in a synthesis to reduce an alkyl halide to a hydrocarbon. In such cases converting the halide to a Grignard reagent and then adding water or an alcohol as a proton source is a satisfactory procedure. Adding D2O to a Grignard reagent is a commonly used method for introducing deuterium into a molecule at a specific location. 14.6 SYNTHESIS OF ALCOHOLS USING GRIGNARD REAGENTS The main synthetic application of Grignard reagents is their reaction with certain carbonyl-containing compounds to produce alcohols. Carbon–carbon bond formation is rapid and exothermic when a Grignard reagent reacts with an aldehyde or ketone. A carbonyl group is quite polar, and its carbon atom is electrophilic. Grignard reagents are nucleophilic and add to carbonyl groups, forming a new carbon–carbon bond. This normally written as COMgX R C R MgX O R MgX C O � � � � Mg THF D2O 1-Bromopropene CH3CH CHBr Propenylmagnesium bromide CH3CH CHMgBr 1-Deuteriopropene (70%) CH3CH CHD (CH3CH2)2NH Diethylamine (stronger acid) CH3CH2CH2CH2Li Butyllithium (stronger base) (CH3CH2)2NLi Lithium diethylamide (weaker base) CH3CH2CH2CH3 Butane (weaker acid) CH3Li Methyllithium (stronger base) NH3 Ammonia (stronger acid: Ka � 1036) CH4 Methane (weaker acid: Ka 1060) LiNH2 Lithium amide (weaker base) CH3CH2MgBr Ethylmagnesium bromide (stronger base) HCPCH Acetylene (stronger acid: Ka 1026) CH3CH3 Ethane (weaker acid: Ka 1062) HCPCMgBr Ethynylmagnesium bromide (weaker base) 14.6 Synthesis of Alcohols Using Grignard Reagents 553 Deuterium is the mass 2 isotope of hydrogen. Deuterium oxide (D2O) is sometimes called “heavy water.” Back Forward Main Menu TOC Study Guide TOC Student OLC MHHE Website���������������������
CHAPTER FOURTEEN Organometallic Compounds addition step leads to an alkoxymagnesium halide, which in the second stage of the syn- thesis is converted to an alcohol by adding aqueous acid R-C-OMgX H,O+ -R-C-OH+ Mg2++X +H,0 Alkoxymagnes Acohol Magnesium Halide Water halide The type of alcohol produced depends on the carbonyl compound. Substituents pres ent on the carbonyl group of an aldehyde or ketone stay there-they become substituents on the carbon that bears the hydroxyl group in the product. Thus as shown in Table 14.3 secondary alcohols, and ketones yield tertiary alcohol e formaldehyde reacts with Grignard reagents to yield primary alcohols, aldehydes yield PROBLEM 14.5 Write the structure of the product of the reaction of propyl agnesium bromide with each of the following. Assume that the reactions are worked up by the addition of dilute aqueous acid none Formaldehyde, HCH benzaldehyde, CHs CH 2-Butanone, CH3CCH2 CH SAMPLE SOLUTION (a) Grignard reagents react with formaldehyde ri- ve or mary alcohols having one more carbon atom than the alkyl halide from which the Grignard reagent was prepared. The product is 1-butanol CHaCH2C CH3 CH2CH2 CH3CH2CH2CH2OH C=O Propylmagnesium bromide 1-Butanol formaldehyde An ability to form carbon-carbon bonds is fundamental to organic synthesis. The addition of Grignard reagents to aldehydes and ketones is one of the most frequently used reactions in synthetic organic chemistry. Not only does it permit the extension of carbon chains, but since the product is an alcohol, a wide variety of subsequent func tional group transformations is possible. 4.7 SYNTHESIS OF ALCOHOLS USING ORGANOLITHIUM REAGENTS Organolithium reagents react with carbonyl groups in the same way that Grignard reagents do. In their reactions with aldehydes and ketones, organolithium reagents are somewhat more reactive than grignard reagents Back Forward Main MenuToc Study Guide ToC Student o MHHE Website
addition step leads to an alkoxymagnesium halide, which in the second stage of the synthesis is converted to an alcohol by adding aqueous acid. The type of alcohol produced depends on the carbonyl compound. Substituents present on the carbonyl group of an aldehyde or ketone stay there—they become substituents on the carbon that bears the hydroxyl group in the product. Thus as shown in Table 14.3, formaldehyde reacts with Grignard reagents to yield primary alcohols, aldehydes yield secondary alcohols, and ketones yield tertiary alcohols. PROBLEM 14.5 Write the structure of the product of the reaction of propylmagnesium bromide with each of the following. Assume that the reactions are worked up by the addition of dilute aqueous acid. (a) (c) (b) (d) SAMPLE SOLUTION (a) Grignard reagents react with formaldehyde to give primary alcohols having one more carbon atom than the alkyl halide from which the Grignard reagent was prepared. The product is 1-butanol. An ability to form carbon–carbon bonds is fundamental to organic synthesis. The addition of Grignard reagents to aldehydes and ketones is one of the most frequently used reactions in synthetic organic chemistry. Not only does it permit the extension of carbon chains, but since the product is an alcohol, a wide variety of subsequent functional group transformations is possible. 14.7 SYNTHESIS OF ALCOHOLS USING ORGANOLITHIUM REAGENTS Organolithium reagents react with carbonyl groups in the same way that Grignard reagents do. In their reactions with aldehydes and ketones, organolithium reagents are somewhat more reactive than Grignard reagents. diethyl ether H3O CH3CH2CH2 MgBr C H H O Propylmagnesium bromide formaldehyde CH3CH2CH2 H H C OMgBr CH3CH2CH2CH2OH 1-Butanol 2-Butanone, CH3CCH2CH3 O Benzaldehyde, C6H5CH O Cyclohexanone, O Formaldehyde, HCH O H3O Hydronium ion H2O Water Mg2 Magnesium ion X Halide ion Alkoxymagnesium halide R C OMgX Alcohol R C OH 554 CHAPTER FOURTEEN Organometallic Compounds Back Forward Main Menu TOC Study Guide TOC Student OLC MHHE Website���������
14.7 Synthesis of Alcohols Using Organolithium Reagents TABLE 14.3 Reactions of Grignard Reagents with Aldehydes and Ketones General equation and specific example Reaction with formaldehyde H Grignard reagents react with formal diethyl dehyde(CH2=o) to give primary alcohols having one more carbol than the Grignard reagent. Grignard Formaldehyde reagent HOH HCH diethyl ethe Cyclohexylmagnesium chloride (64-69% Reaction with aldehydes Grignard (RCH=O)to give secondary alcohols. RMgx Grignard Aldehyde Secondary Secondary alkoxymagnesium CH3 (CH 2)4CH2MgBr CH3 CH 1. diethyl ethe CH3(CH2)4CH2 CHCH3 HexyImagnesium Ethanal 2-Octanol (84%) Reaction with ketones Grignard diethyl RMgX R'CR OMaX reagents react with ketones(RCr) to give tertiary alcohols Grignard Ketone ertiary alkoxymagnesiun alcohol CHaMgCI 1. diethyl eth 2.H2O H3C Methylmagnesium Cyclopentanone 1-Methylcyclopentanol chloride Back Forward Main MenuToc Study Guide ToC Student o MHHE Website
14.7 Synthesis of Alcohols Using Organolithium Reagents 555 TABLE 14.3 Reactions of Grignard Reagents with Aldehydes and Ketones Reaction Reaction with formaldehyde Grignard reagents react with formaldehyde (CH2œO) to give primary alcohols having one more carbon than the Grignard reagent. Reaction with aldehydes Grignard reagents react with aldehydes (RCHœO) to give secondary alcohols. Reaction with ketones Grignard reagents react with ketones (RCR�) to give tertiary alcohols. O X General equation and specific example RMgX Grignard reagent Formaldehyde HCH O diethyl ether H3O OMgX H R C H Primary alkoxymagnesium halide OH H R C H Primary alcohol RMgX Grignard reagent Aldehyde R�CH O diethyl ether H3O OMgX H R C R� Secondary alkoxymagnesium halide OH H R C R� Secondary alcohol RMgX Grignard reagent Ketone R�CR O diethyl ether H3O R C OMgX R� R Tertiary alkoxymagnesium halide R C OH R� R Tertiary alcohol MgCl Cyclohexylmagnesium chloride CH2OH Cyclohexylmethanol (64–69%) Formaldehyde HCH O 1. diethyl ether 2. H3O CH3(CH2)4CH2MgBr Hexylmagnesium bromide Ethanal (acetaldehyde) CH3CH O 2-Octanol (84%) CH3(CH2)4CH2CHCH3 OH 1. diethyl ether 2. H3O CH3MgCl Methylmagnesium chloride O Cyclopentanone 1-Methylcyclopentanol (62%) H3C OH 1. diethyl ether 2. H3O Back Forward Main Menu TOC Study Guide TOC Student OLC MHHE Website������������
