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Structures of Aldehydes and Ketones. Both aldehydes and ketones contain a carbonyl group Aldehydes have at least one H attached, while ketones have two C’s attached to the carbonyl A carbonyl consists of a C double-bonded to an O
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Structures of Aldehydes and Ketones • Both aldehydes and ketones contain a carbonyl group • Aldehydes have at least one H attached, while ketones have two C’s attached to the carbonyl • A carbonyl consists of a C double-bonded to an O • Like in an alkene, the double bond consists of one sigma and one pi bond • The carbonyl is a very polar group - O is more electronegative than C, so C-O bonds are polar - Also, the carbonyl has two resonance forms - This polarity makes carbonyls chemically reactive
Naming Ketones • Parent name ends in -one • Find longest chain containing the carbonyl group • Number C’s starting at end nearest carbonyl group • Locate and number substituents and give full name - use a number to indicate position of carbonyl group - cyclic ketones have cyclo- before the parent name; numbering begins at the carbonyl group, going in direction that gives substituents lowest possible numbers - use a prefix (di-, tri-) to indicate multiple carbonyl groups in a compound
Naming Aldehydes • Parent name ends in -al • Find longest chain containing the carbonyl group • Number C’s starting at end nearest carbonyl group • Locate and number substituents and give full name - aldehydes take precedence over ketones and alcohols in naming - ketones are called oxo as a secondary group - alcohols are called hydroxy as a secondary group - the smallest aldehydes are usually named with common names - we will not name cyclic aldehydes (except benzaldehyde)
Nomenclature • because the carbonyl group of an aldehyde can only be at the end of a parent chain and numbering must start with it as carbon-1, there is no need to use a number to locate the aldehyde group • for unsaturated aldehydes, indicate the presence of a carbon-carbon double bond and an aldehyde by changing the ending of the parent alkane from -ane to -enal; show the location of the carbon-carbon double bond by the number of its first carbon
Nomenclature • the IUPAC system retains common names for some aldehydes, including these three
Physical Properties of Aldehydes and Ketones • Because the carbonyl group is polar, aldehydes and ketones have higher boiling points than hydrocarbons • However, they have no H attached to the O, so do not have hydrogen bonding, and have lower boiling points than alcohols • Like ethers, aldehydes and ketones can hydrogen bond with water, so those with less than 5 carbons are generally soluble in water • Aldehydes and ketones can be flammable and/or toxic, though generally not highly so • They usually have strong odors, and are often used as flavorings or scents
Oxidation of Aldehydes • Recall that aldehydes and ketones are formed by the oxidation of primary and secondary alcohols, respectively • Also recall that aldehydes are readily oxidized to carboxylic acids, but ketones are not • Tollens’ reagent (silver nitrate plus ammonia) can be used to distinguish between ketones and aldehydes - with aldehydes the Ag2+ is reduced to elemental silver, which forms a mirror-like coat on the reaction container • Sugars (like glucose) often contain a hydroxy group adjacent to an aldehyde - Benedict’s reagent (Fehlings reagent) (CuSO4) can be used to test for this type of aldehyde; the blue Cu2+ forms Cu2O, a red solid
Oxidation • Aldehydes are oxidized to carboxylic acids by a variety of oxidizing agents, including potassium dichromate • liquid aldehydes are so sensitive to oxidation by O2 of the air that they must be protected from contact with air during storage
Oxidation • Ketones resist oxidation by most oxidizing agents, including potassium dichromate and molecular oxygen • Tollens’ reagent is specific for the oxidation of aldehydes; if done properly, silver deposits on the walls of the container as a silver mirror
Reduction of Aldehydes and Ketones • Reduction can be defined as a loss in bonds to O or a gain in bonds to H • Aldehydes and ketones can be reduced to form alcohols - Aldehydes form primary alcohols - ketones form secondary alcohols • Many different reducing agents can be used, including H2, LiAlH4 (lithium aluminum hydride) and NaBH4 (sodium borohydride) • However, NaBH4 is usually the reagent of choice - hydrogenation will also reduce alkenes and alkynes if present - LiAlH4 is more reactive than NaBH4, but reacts violently with water and explodes when heated above 120º C
Reduction • The carbonyl group of an aldehyde or ketone is reduced to an -CHOH group by hydrogen in the presence of a transition-metal catalyst • reduction of an aldehyde gives a primary alcohol • reduction a ketone gives a secondary alcohol
Reduction • reduction by NaBH4 does not affect a carbon-carbon double bond
Reduction • In biological systems, the agent for the reduction of aldehydes and ketones is the reduced form of nicotinamide adenine dinucleotide, abbreviated NADH (this reducing agent, like NaBH4, delivers a hydride ion to the carbonyl carbon of the aldehyde or ketone • reduction of pyruvate, the end product of glycolysis, by NADH gives lactate
Addition of Water to Aldehydes and Ketones • H2O can add across the carbonyl of an aldehyde or a ketone, similar to the addition of H2O to an alkene • A partial positive H from water bonds to the partial negative carbonyl O, and the partial negative O from water bonds to the partial positive carbonyl C • The product of this reversible reaction is a hydrate (a 1,1-diol) • In general, the equilibrium favors the carbonyl compound, but for some small aldehydes the hydrate is favored • The reaction can be catalyzed by either acid or base
Mechanism of Acid-Catalyzed Hydration of Formaldehyde • First, the carbonyl O is protonated by the acid catalyst • Next, H2O attacks the carbonyl carbon to form a protonated hydrate • Finally, H2O removes the proton to form the hydrate
Addition of Alcohols to Aldehydes and Ketones • Alcohols can add to aldehydes and ketones using an acid catalyst • Addition of 2 alcohols produces an acetal (a diether) • The reaction intermediate, after addition of one alcohol, is a hemiacetal (not usually isolated) • This is a reversible reaction - removal of H2O favors acetal - addition of H2O favors aldehyde or ketone • Acetals are often used as protecting groups in organic synthesis
Formation of Cyclic Hemiacetals • When an aldehyde or a ketone is in the same molecule as an alcohol, a cyclic hemiacetal can form • These are more stable than the non-cyclic ones and can be isolated • Sugars, like glucose and fructose, exist primarily in the cyclic hemiacetal form • When an alcohol adds to a cyclic hemiacetal, a cyclic acetal is formed (this is how sugars bond together in polysaccharides)
Addition of Alcohols • all steps in hemiacetal and acetal formation are reversible • as with any other equilibrium, we can drive this one in either direction by using Le Chatelier's principle • to drive it to the right, we either use a large excess of alcohol or remove water from the equilibrium mixture • to drive it to the left, we use a large excess of water
Keto-Enol Tautomerism • A carbon atom adjacent to a carbonyl group is called an a-carbon, and a hydrogen atom bonded to it is called an a-hydrogen
Keto-Enol Tautomerism • A carbonyl compound that has a hydrogen on an a-carbon is in equilibrium with a constitutional isomer called an enol • the name “enol” is derived from the IUPAC designation of it as both an alkene (-en-) and an alcohol (-ol) in a keto-enol equilibrium, the keto form generally predominates