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Reactions of aldehydes and ketones : oxidation reduction nucleophilic addition Aldehydes are easily oxidized, ketones are not. Aldehydes are more reactive in nucleophilic additions than ketones. alkane. alcohol. reduction. reduction. aldehyde ketone. addition product. nucleophilic
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Reactions of aldehydes and ketones: • oxidation • reduction • nucleophilic addition • Aldehydes are easily oxidized, ketones are not. • Aldehydes are more reactive in nucleophilic additions than ketones.
alkane alcohol reduction reduction aldehyde ketone addition product nucleophilic addition oxidation carboxylic acid
Mechanism:nucleophilic addition to carbonyl,acid catalyzed 1) 2) 3)
Aldehydes & ketones, reactions: • Oxidation • Reduction • Addition of cyanide • Addition of derivatives of ammonia • Addition of alcohols • Cannizzaro reaction • Addition of Grignard reagents • 8) (Alpha-halogenation of ketones) • 9) (Addition of carbanions)
1) Oxidation • Aldehydes(very easily oxidized!) • CH3CH2CH2CH=O + KMnO4, etc. CH3CH2CH2COOH • carboxylic acid • CH3CH2CH2CH=O + Ag+ CH3CH2CH2COO- + Ag • Tollen’s test for easily oxidized compounds like aldehydes. • (AgNO3, NH4OH(aq)) Silver mirror
Ketones only oxidize under vigorous conditions via the enol.
b) Methyl ketones: Yellow ppt test for methyl ketones
2) Reduction: • To alcohols
Reduction b) To hydrocarbons
1) 2)
Cyanohydrins have two functional groups plus one additional carbon. Nitriles can be hydrolyzed to carboxylic acids in acid or base:
1) 2) 3)
melting points of derivatives ketones bpsemi- 2,4-dinitro- oxime carbazone phenylhydrazone 2-nonanone 195 119 56 acetophenone 202 199 240 60 menthone 209 189 146 59 2-methylacetophenone 214 205 159 61 1-phenyl-2-propanone 216 200 156 70 propiophenone 220 174 191 54 3-methylacetophenone 220 198 207 55 isobutyrophenone 222 181 163 94
Cannizzaro reaction. (self oxidation/reduction) • a reaction ofaldehydes without α-hydrogens
Formaldehyde is the most easily oxidized aldehyde. When mixed with another aldehyde that doesn’t have any alpha-hydrogens and conc. NaOH, all of the formaldehyde is oxidized and all of the other aldehyde is reduced. Crossed Cannizzaro:
1) 2)
#3 synthesis of alcohols. Used to build larger molecules from smaller organic compounds.
Aldehydes & ketones, reactions: • Oxidation • Reduction • Addition of cyanide • Addition of derivatives of ammonia • Addition of alcohols • Cannizzaro reaction • Addition of Grignard reagents • 8) (Alpha-halogenation of ketones) • 9) (Addition of carbanions)
Planning a Grignard synthesis of an alcohol: • The alcohol carbon comes from the carbonyl compound. • The new carbon-carbon bond is to the alcohol carbon. New carbon-carbon bond
“The Grignard Song” (sung to the tune of “America the Beautiful”) Harry Wasserman The carbonyl is polarized, the carbon end is plus. A nucleophile will thus attack the carbon nucleus. The Grignard yields an alcohol of types there are but three. It makes a bond that corresponds from “C” to shining “C.”
HX Mg ROH RX RMgX larger alcohol H2O ox. R´OH -C=O
Stockroom: alcohols of four-carbons or less: (methanol, ethanol, 1-propanol, 2-propanol, 1-butanol, 2-butanol, 2-methyl-2-propanol, 2-methyl-1-propanol.) benzene cyclohexanol any needed inorganic reagents or solvents.
Grignard synthesis of 4-methyl-2-pentanol from alcohols of four-carbons or less: Step one: determine the carbonyl compound and Grignard reagent that you would use: H2O CH3 CH3CHCH2MgBr + CH3CH=O CH3 CH3CHCH2CHCH3 OH Step two: show the syntheses of the Grignard reagent and the carbonyl compound from alcohols…
CH3 PBr3 CH3 Mg CH3 CH3CHCH2OH CH3CHCH2Br CH3CHCH2MgBr H+ K2Cr2O7 CH3 CH3CH2OH CH3CH=O CH3CHCH2CHCH3 special cond. OH 4-methyl-2-pentanol
ketone aldehyde RCOOH ROH ROR alkene RX Alcohols are central to organic syntheses RH alkyne
HX Mg ROH RX RMgX larger alcohol H2O ox. R´OH -C=O
Using the Grignard synthesis of alcohols we can make any alcohol that we need from a few simple alcohols. From those alcohols we can synthesize alkanes, alkenes, alkynes, alkyl halides, ethers, aldehydes, ketones, carboxylic acids… eg. Outline all steps in a possible laboratory synthesis of 3-methyl-1-butene from alcohols of four carbons or less. CH3 CH3CHCH=CH2
Retrosynthesis: alkenes, syntheses: 1. Dehydrohalogenation of an alkyl halide 2. Dehydration of an alcohol 3. Dehalogenation of a vicinal dihalide 4. Reduction of an alkyne Methods 3 & 4 start with compounds that are in turn made from alkenes.
Dehydration of an alcohol? CH3 H+ CH3CHCHCH3 yields a mixture of alkenes OH CH3 H+ CH3CHCH2CH2-OH yields a mixture of alkenes E1 mechanism via carbocation!
Dehydrohalogenation of an alkyl halide? CH3 KOH(alc) CH3CHCHCH3 yields a mixture of alkenes Br CH3 KOH(alc) CH3 CH3CHCH2CH2-Br CH3CHCH=CH2 only product E2 mechanism, no carbocation, no rearrangement
CH3 PBr3 CH3 CH3CHCH2CH2-OH CH3CHCH2CH2-Br 1o alcohol, SN2 mechanism, no rearrangement! CH3 KOH(alc) CH3 CH3CHCH2CH2-Br CH3CHCH=CH2 Use the Grignard synthesis to synthesize the intermediate alcohol from the starting materials.