Upload
phamkiet
View
214
Download
0
Embed Size (px)
Citation preview
Master
Acid derivativesCarboxylic
MASTERMASTER
2011
PrincessMaster
5/18/2011
1
1
2
2
2
Carboxylic Acid Derivatives
1. Background and Properties
The important classes of organic compounds known as alcohols, phenols, ethers, amines and halides consist of alkyl and/or aryl groups bonded to hydroxyl, alkoxyl, amino and halo substituents respectively. If these same functional groups are attached to an acyl group (RCO–) their properties are substantially changed, and they are designated as carboxylic acid derivatives. Car-boxylic acids have a hydroxyl group bonded to an acyl group, and their functional derivatives are prepared by replacement of the hydroxyl group with substituents, such as halo, alkoxyl, amino and acyloxy. Some examples of these functional derivatives were displayed earlier.The following table lists some representative derivatives and their boiling points. An aldehyde and ketone of equivalent molecular weight are also listed for comparison. Boiling points are given for 760 torr (atmospheric pressure), and those listed as a range are estimated from values obtained at lower pressures. As noted earlier, the relatively high boiling point of carboxylic acids is due to extensive hydrogen bonded dimerization. Similar hydrogen bonding occurs between molecules of 1º and 2º-amides (amides having at least one N–H bond), and the first three compounds in the table serve as hydrogen bonding examples.
Physical Properties of Some Carboxylic Acid Derivatives
Formula IUPAC Name Molecular Weight Boiling Point Water Solubility
CH3(CH2)2CO2H butanoic acid 88 164 ºC very soluble
CH3(CH2)2CONH2 butanamide 87 216-220 ºC soluble
CH3CH2CONHCH3 N-methylpropanamide 87 205 -210 ºC soluble
CH3CON(CH3)2 N,N-dimethylethanamide 87 166 ºC very soluble
HCON(CH3)CH2CH3 N-ethyl, N-methylmethanamide 87 170-180 ºC very soluble
CH3(CH2)3CN pentanenitrile 83 141 ºC slightly soluble
CH3CO2CHO ethanoic methanoic anhydride
88 105-112 ºC reacts with water
CH3CH2CO2CH3 methyl propanoate 88 80 ºC slightly soluble
CH3CO2C2H5 ethyl ethanoate 88 77 ºC moderately soluble
CH3CH2COCl propanoyl chloride 92.5 80 ºC reacts with water
CH3(CH2)3CHO pentanal 86 103 ºC slightly soluble
CH3(CH2)2COCH3 2-pentanone 86 102 ºC slightly soluble
The last nine entries in the above table cannot function as hydrogen bond donors, so hydrogen bonded dimers and aggregates are not possible. The relatively high boiling points of equivalent 3º-amides and nitriles are probably due to the high polarity of these functions. Indeed, if hydrogen bonding is not present, the boiling points of comparable sized compounds correlate reasonably well with their dipole moments.
Back to the TopNomenclature of Carboxylic Acid Derivatives hree examples of acyl groups having specific names were noted earlier. These are often used in common names of compounds. In the following examples the IUPAC names are color coded, and common names are given in parentheses.
• Esters: The alkyl group is named first, followed by a derived name for the acyl group, the oic or ic suffix in the acid name is replaced by ate.
2
34
3
4
56
3
e.g. CH3(CH2)2CO2C2H5 is ethyl butanoate (or ethyl butyrate). Cyclic esters are called lactones. A Greek letter identifies the location of the alkyl oxygen relative to the carboxyl carbonyl group.• Acid Halides: The acyl group is named first, followed by the halogen name as a separate word. e.g. CH3CH2COCl is propanoyl chloride (or propionyl chloride).• Anhydrides: The name of the related acid(s) is used first, followed by the separate word "anhydride". e.g. (CH3(CH2)2CO)2O is butanoic anhydride & CH3COOCOCH2CH3 is ethanoic propanoic anhydride (or acetic propionic anhy-dride).• Amides: The name of the related acid is used first and the oic acid or ic acid suffix is replaced by amide (only for 1º-amides). e.g. CH3CONH2 is ethanamide (or acetamide). 2º & 3º-amides have alkyl substituents on the nitrogen atom. These are designated by "N-alkyl" term(s) at the beginning of the name. e.g. CH3(CH2)2CONHC2H5 is N-ethylbutanamide; & HCON(CH3)2 is N,N-dimethylmethanamide (or N,N-dimethylformamide). Cyclic amides are called lactams. A Greek letter identifies the location of the nitrogen on the alkyl chain relative to the carboxyl car-bonyl group.• Nitriles: Simple acyclic nitriles are named by adding nitrile as a suffix to the name of the corresponding alkane (same number of car-bon atoms). Chain numbering begins with the nitrile carbon . Commonly, the oic acid or ic acid ending of the corresponding carboxylic acid is re-placed by onitrile. A nitrile substituent, e.g. on a ring, is named carbonitrile. e.g. (CH3)2CHCH2C≡N is 3-methylbutanenitrile (or isovaleronitrile).
Acyl Chlorides Functional group suffix = oyl chloride (review)
Anhydrides Functional group suffix = alkanoic anhydride ( review)
Thioesters Functional group suffix = alkyl -oate Functional group prefix = alkoxycarbonyl- or carbalkoxy-
Esters Functional group suffix = alkyl -oate (review) Functional group prefix = alkoxycarbonyl- or carbalkoxy- Cyclic esters are called lactones
Carboxylic Acids Functional group suffix = -oic acid (review) Functional group prefix = carboxy-
Amides Functional group suffix = amide (review) Functional group prefix = carbamoyl- Cyclic amides are called lactams
Nitriles Functional group suffix = nitrile or -onitrile (review) Functional group prefix = cyano-
Acyl Halides or Acid Halides
Nomenclature Formula
Functional class name = acyl or acid halide
Substituent suffix = -oyl halide
Acyl or acid halides are derivatives of carboxylic acids.
3
78
910
4
The root name is based on the longest chain including the carbonyl group of the acyl group.
Since the acyl group is at the end of the chain, the C=O carbon must be C1.
The acyl halide suffix is appended after the hydrocarbon suffix minus the "e" : e.g. -ane + -oyl halide = -anoyl halide etc.
The most common halide encountered is the chloride, hence acyl or acid chlorides, e.g. ethanoyl chlorid
Functional group is an acyl halide therefore suffix = -oyl chloride
Hydrocarbon structure is an alkane therefore -an-
The longest continuous chain is C2 therefore root = eth
ethanoyl chlorideCH3C(=O)Cl
Functional group is an acyl halide therefore suffix = -oyl chloride
Hydrocarbon structure is an alkane therefore -an-
The longest continuous chain is C4 therefore root = but
butanoyl chlorideCH3CH2CH2C(=O)Cl
Functional group is an acyl halide therefore suffix = -oyl chloride
Hydrocarbon structure is an alkane therefore -an-
The longest continuous chain is C3 therefore root = prop
The branch is a C1 alkyl group i.e. a methyl group
The functional groups requires numbering from the right as drawn, the sub-stituent locant is 2-
2-methylpropanoyl chloride
(CH3)2CHC(=O)Cl
Acid Anhydrides
Nomenclature Formula
Functional class name = alkanoic anhydride
Substituent suffix = -oic anhydride
As the name implies, acid anyhydrides are derivatives of carboxylic acids.
In principle, they can be symmetric (where the two R groups are identical) or asymmetric (where the two R groups are differ-ent).
Symmetric anhydrides are the most common, they are named as alkanoic anhydrides
Asymmetric anhydrides are name in a similar fashion listing the alkyl groups in alphabetical order.
Cyclic anhydrides derived from dicarboxylic acids are name as -dioic anhydrides.
Functional group is an acid anhydride therefore suffix = -oic anhydride
Hydrocarbon structure is an alkane therefore -an-
The longest continuous chain is C2 therefore root = eth
ethanoic anhydrideCH3C(=O)OC(=O)CH3
Functional group is an acid anhydride therefore suffix = -oic anhydride
Hydrocarbon structure is an alkane therefore -an-
The longest continuous chain is C4 therefore root = but
The other group is C3 = prop
butanoic propanoic anhydride
4
1112
1314
5
Functional group is a cyclic acid anhydride therefore suffix = -dioic an-hydride
Hydrocarbon structure is an alkane therefore -an-
The longest continuous chain is C5 therefore root = pent
pentandioic anhydride
Back to the TopEsters
Nomenclature Formula
Functional class name = alkyl alkanoate
Substituent suffix = -oate
Esters are alkyl derivatives of carboxylic acids.
The easiest way to deal with naming esters is to recognise the carboxylic acid and the alcohol that they can be prepared from.
The general ester, RCO2R' can be derived from the carboxylic acid RCO2H and the alcohol HOR'
The first component of an ester name, the alkyl is derived from the alcohol, R'OH.
The second component of an ester name, the -oate is derived from the carboxylic acid, RCO2H.
Alcohol component
o the root name is based on the longest chain containing the -OH group.
o The chain is numbered so as to give the -OH the lowest possible number.
Carboxylic acid component
o the root name is based on the longest chain including the carbonyl group.
o Since the carboxylic acid group is at the end of the chain, it must be C1.
o The ester suffix for the acid component is appended after the hydrocarbon suffix minus the "e" : e.g. -ane + -oate = -anoate etc.
The complete ester name is the alkyl alkanoate
Functional group is an ester
The alcohol component here is methanol, so the alkyl = methyl
The acid component here is propanoic acid, so propanoate
methyl propanoate
CH3CH2C(=O)OCH3
Back to the TopAmidesNomenclature Formula
Functional class name = alkyl alkanamide
Substituent suffix = -amide
Amides are amine derivatives of carboxylic acids.
The root name is based on the longest chain including the carbonyl group of the amide group.
Since the amide group is at the end of the chain, the C=O carbon must be C1.
The amide suffix is appended after the hydrocarbon suffix minus the "e" : e.g. -ane + -amide = -anamide etc.
5
1516
1718
6
If the amide nitrogen is substituted, the these substituents are given N- as the locant.
The N- locant is listed first.
Functional group is an amide therefore suffix = -amide
Hydrocarbon structure is an alkane therefore -an-
The longest continuous chain is C4 therefore root = but
butanamide CH3CH2CH2C(=O)NH2
Functional group is an amide therefore suffix = -amide
Hydrocarbon structure is an alkane therefore -ane
The longest continuous chain is C4 therefore root = but
The nitrogen substituent is C1 i.e. an N-methyl group
N-methylbutanamide
CH3CH2CH2C(=O)N(CH3)H
Functional group is an amide therefore suffix = -amide
Hydrocarbon structure is an alkane therefore -ane
The longest continuous chain is C2 therefore root = eth
The two nitrogen substituents are C1 i.e. an N-methyl group
There are two methyl groups, therefore multiplier = di-
N,N-dimethylethanamide
CH3C(=O)N(CH3)2
Nitriles
Nomenclature Formula
Functional class = alkyl cyanide
Functional group suffix = nitrile or -onitrile
Substituent prefix = cyano-
Notes :
The cyano prefix is used in a very similar manner to haloalkanes.
The cyano nomenclature is most common when the alkyl group is simple.
The nitrile suffix is used in a very similar manner to carboxylic acids.
Cyano substituent style: The root name is based on the longest chain with the -C≡N as a substituent.
This root give the alkane part of the name.
The chain is numbered so as to give the -C≡N group the lowest possible locant number
Nitrile style: The root name is based on the longest chain including the carbon of the nitrile group.
This root give the alkyl part of the name.
Since the nitrile must be at the end of the chain, it must be C1 and no locant needs to be specified.
Nitriles can also be named by replacing the -oic acid suffix of the corresponding carboxylic acid with -onitrile.
Cyano substituent style:
Functional group is an alkane, therefore suffix = -ane
6
1920
2122
7
The longest continuous chain is C3 therefore root = prop
The substituent is a -CN therefore prefix = cyano
The first point of difference rule requires numbering from the right as drawn, the sub-stituent locant is 1-
1-cyanopropane
Nitrile style: Functional group is a -C≡N, therefore suffix = -nitrile
Hydrocarbon structure is an alkane therefore -ane
The longest continuous chain is C4 therefore root = but
butanenitrile
CH3CH2CH2C≡N
Back to the TopStructure of Carboxylic Acid Derivatives
The carbonyl group consists of an O atom bonded to a C atom via a double bond in a planar, sp2 hybridisation model similar to that of a ketone or an alkene.
The heteroatom group is connected to this C=O unit via a s bond.
To see these features, compare the JMOL images to the below.
JMOL images of the other carboxylic acid derivatives can be found on the previous page.
The resonance interaction of the carbonyl C=O with the lone pair of the adjacent heteroatom (structure III) has important im-plications on the reactivity
It also has implications for structure... Look at the JMOL image of the amide to the right.
Amines and ammonia are usually pyramidal .
The planar sp2 N system allows the N lone pair to align with the C=O system (see image below, with the other bonds omit-ted for clarity)
The resonance interaction in the amide results in the C-N bond having some double bond character (shorter, restricted rota-tion)
Nitriles are slightly different to the other derivatives in that they involved a triple bond.
Nitriles consists of a N atom bonded to a C atom via a triple bond in a linear, sp hybridisation model similar to that of an al-kyne. Compare the JMOL images to the right.
Reactions of Carboxylic Acid Derivatives
1. Acyl Group Substitution
This is probably the single most important reaction of carboxylic acid derivatives. The overall transformation is defined by the fol-lowing equation, and may be classified either as nucleophilic substitution at an acyl group or as acylation of a nucleophile. For certain nucleophilic reagents the reaction may assume other names as well. If Nuc-H is water the reaction is often called hy-drolysis, if Nuc–H is an alcohol the reaction is called alcoholysis, and for ammonia and amines it is called aminolysis.
7
2324
2526
8
Different carboxylic acid derivatives have very different reactivities, acyl chlorides and bromides being the most reactive and amides the least reactive, as noted in the following qualitatively ordered list. The change in reactivity is dramatic. In homogeneous solvent systems, reaction of acyl chlorides with water occurs rapidly, and does not require heating or catalysts. Amides, on the other hand, react with water only in the presence of strong acid or base catalysts and external heating.
Reactivity: acyl halides > anhydrides >> esters ≈ acids >> amides
Because of these differences, the conversion of one type of acid derivative into another is generally restricted to those outlined in the following diagram. Methods for converting carboxylic acids into these derivatives were shown in a previous section, but the amide and anhydride preparations were not general and required strong heating. A better and more general anhydride synthesis can be achieved from acyl chlorides, and amides are easily made from any of the more reactive derivatives. Specific examples of these conversions will be displayed by clicking on the product formula. The carboxylic acids themselves are not an essential part of this diagram, although all the derivatives shown can be hydrolyzed to the carboxylic acid state (light blue formulas and reaction ar-rows). Base catalyzed hydrolysis produces carboxylate salts.
Before proceeding further, it is important to review the general mechanism by means of which all these acyl transfer or acylation reactions take place. Indeed, an alert reader may well be puzzled by the facility of these nucleophilic substitution reactions. After all, it was previously noted that halogens bonded to sp2 or sp hybridized carbon atoms do not usually undergo substitution reac-tions with nucleophilic reagents. Furthermore, such substitution reactions of alcohols and ethers are rare, except in the presence of strong mineral acids. Clearly, the mechanism by which acylation reactions occur must be different from the SN1 and SN2 proce-dures described earlier.In any substitution reaction two things must happen. The bond from the substrate to the leaving group must be broken, and a bond to the replacement group must be formed. The timing of these events may vary with the reacting system. In nucleophilic substitu-tion reactions of alkyl compounds examples of bond-breaking preceding bond-making (the SN1 mechanism), and of bond-breaking and bond-making occuring simultaneously (the SN2 mechanism) were observed. On the other hand, for most cases of electrophilic aromatic substitution bond-making preceded bond-breaking.
As illustrated in the following diagram, acylation reactions generally take place by an addition-elimination process in which a nu-cleophilic reactant bonds to the electrophilic carbonyl carbon atom to create a tetrahedral intermediate. This tetrahedral intermedi-ate then undergoes an elimination to yield the products. In this two-stage mechanism bond formation occurs before bond cleavage, and the carbonyl carbon atom undergoes a hybridization change from sp2 to sp3 and back again. The facility with which nucleophilic reagents add to a carbonyl group was noted earlier for aldehydes and ketones.
Back to the TopAcid and base-catalyzed variations of this mechanism will be displayed in turn as the "Mechanism Toggle" button is clicked. Also, a specific example of acyl chloride formation from the reaction of a carboxylic acid with thionyl chloride will be shown. The number of individual steps in these mechanisms vary, but the essential characteristic of the overall transformation is that of addition followed by elimination. Acid catalysts act to increase the electrophilicity of the acyl reactant; whereas, base catalysts act on the nucle-ophilic reactant to increase its reactivity. In principle all steps are reversible, but in practice many reactions of this kind are irre-versible unless changes in the reactants and conditions are made. The acid-catalyzed formation of esters from carboxylic acids and alcohols, described earlier, is a good example of a reversible acylation reaction, the products being determined by the addition or removal of water from the system. The reaction of an acyl chloride with an alcohol also gives an ester, but this conversion can-not be reversed by adding HCl to the reaction mixture.
Thus far we have not explained the marked variation, noted above, in the reactivity of different carboxylic acid derivatives. The dis-tinguishing carbonyl substituents in these compounds are: chloro (acyl chlorides), acyloxy (anhydrides), alkoxy (esters) and amino
8
2728
2930
9
(amides). All of these substituents have bonds originating from atoms of relatively high electronegativity (Cl, O & N). They are therefore inductively electron withdrawing when bonded to carbon, as shown in the diagram on the right. The consequences of such inductive electron withdrawal on the acidity of carboxylic acids was previously noted.
When these substituents are attached to an sp2 carbon that is part of a π-electron system, a similar inductive effect occurs, but p-π conjugation moves electron density in the opposite direction. By clicking the "Toggle Effect" button the electron shift in both effects will be displayed sequentially. This competition between inductive electron withdrawal and conjugative electron donation was dis-
cussed earlier in the context of substituent effects on electrophilic aromatic substitution. Here, it was noted that amino groups were strongly electron donating (resonance effect >> inductive effect), alkoxy groups were slightly less activating, acyloxy groups still
less activating (resonance effect > inductive effect) and chlorine was deactivating (inductive effect > resonance effect). In the illus-tration on the right, R and Z represent the remainder of a benzene ring.
This analysis also predicts the influence these substituent groups have on the reactivity of carboxylic acid derivatives toward nucle-ophiles (Z = O in the illustration). Inductive electron withdrawal by Y increases the electrophilic character of the carbonyl carbon, and increases its reactivity toward nucleophiles. Thus, acyl chlorides (Y = Cl) are the most reactive of the derivatives. Resonance
electron donation by Y decreases the electrophilic character of the carbonyl carbon. The strongest resonance effect occurs in amides, which exhibit substantial carbon-nitrogen double bond character and are the least reactive of the derivatives. An interest-ing exception to the low reactivity of amides is found in beta-lactams such as penicillin G. The angle strain introduced by the four-
membered ring reduces the importance of resonance, the non-bonding electron pair remaining localized on the pyramidally shaped nitrogen. Finally, anhydrides and esters have intermediate reactivities, with anhydrides being more reactive than esters.
The first three examples concern reactions of acyl chlorides, the most reactive acylating reagents discussed here. Although amines are among the most reactive nucleophiles, only 1º and 2º-amines give stable amide products. Reaction of 3º-amines with strong acylating reagents may gener-ate acylammonium species reversibly (see below), but these are as reactive as acyl chlorides and will have only a very short existence. This ex-plains why reactions #2 & 3 do not give amide products.
RCOCl + R'3N RCONR'3(+) Cl(–) (an acylammonium salt)
Reactions #4 & 5 display the acylating capability of anhydrides. Bear in mind that anhydrides may also be used as reagents in Friedel-Crafts acylation reactions. Esters are less reactive acylating reagents than anhydrides, and the ester exchange reaction (#6) requires a strong acid or base catalyst. The last example demonstrates that nitrogen is generally more nucleophilic than oxygen. Indeed, it is often possible to carry out reactions of amines with acyl chlorides and anhydrides in aqueous sodium hydroxide solution! Not only is the amine more nucleophilic than wa-ter, but the acylating reagent is generally not soluble in or miscible with water, reducing the rate of its hydrolysis.No acylation reactions of amides were shown in these problems. The most important such reaction is hydrolysis, and this normally requires heat and strong acid or base catalysts. One example, illustrating both types of catalysis, is shown here. Mechanisms for catalyzed reactions of this kind were presented earlier.
R–CO2(–) + CH3NH2
OH(–) & heat R–CO–NH(CH3) + H2O
H(+) & heatR–CO2H + CH3NH3
(+)
Other Acylation Reagents and TechniquesBecause acylation is such an important and widely used transformation, the general reactions described above have been supple-mented by many novel procedures and reagents that accomplish similar overall change.
Nitriles
Although they do not have a carbonyl group, nitriles are often treated as derivatives of carboxylic acids. Hydrolysis of nitriles to carboxylic acids was described earlier, and requires reaction conditions (catalysts and heat) similar to those needed to hydrolyze amides. This is not surpris-ing, since addition of water to the carbon-nitrogen triple bond gives an imino intermediate which tautomerizes to an amide.
R–C≡N + H2O acid or base
R–C(OH)=NH R–CO–NH2
2. Reduction
Reductions of carboxylic acid derivatives might be expected to lead either to aldehydes or alcohols, functional groups having a lower oxidation state of the carboxyl carbon. Indeed, it was noted earlier that carboxylic acids themselves are reduced to alcohols by lithium aluminum hydride. At this point it will be useful to consider three kinds of reductions: (i) catalytic hydrogenation (ii) complex metal hydride reductions (iii) diborane reduction.
9
3132
3334
10
Catalytic Hydrogenation
As a rule, the carbonyl group does not add hydrogen as readily as do the carbon-carbon double and triple bonds. Thus, it is fairly easy to reduce an alkene or alkyne function without affecting any carbonyl functions in the same molecule. By using a platinum cat-alyst and increased temperature and pressure, it is possible to reduce aldehydes and ketones to alcohols, but carboxylic acids, es-ters and amides are comparatively unreactive. The exceptional reactivity of acyl halides, on the other hand, facilitates their reduc-tion under mild conditions, by using a poisoned palladium catalyst similar to that used for the partial reduction of alkynes to alkenes. This reduction stops at the aldehyde stage, providing us with a useful two-step procedure for converting carboxylic acids to aldehydes, as reaction #1 below demonstrates. Equivalent reductions of anhydrides have not been reported, but we might spec-ulate that they would be reduced more easily than esters. The only other reduction of a carboxylic acid derivative that is widely used is that of nitriles to 1º-amines. Examples of these reductions are provided in the following diagram.
he second and third equations illustrate the extreme difference in hydrogenation reactivity between esters and nitriles. This is futher demon-strated by the last reaction, in which a nitrile is preferentially reduced in the presence of a carbonyl group and two benzene rings. The resulting 1º-amine immediately reacts with the carbonyl function to give a cyclic enamine product (colored light blue).In most nitrile reductions ammonia is added to inhibit the formation of a 2º-amine by-product. This may occur by way of an intermediate alde-hyde imine created by addition of the first equivalent of hydrogen. The following equations show how such an imine species might react with the 1º-amine product to give a substituted imine (2nd equation), which would then add hydrogen to generate a 2º-amine. Excess ammonia shifts the imine equilibrium to the left, as written below.
(1) R–C≡N + H2
catalyst
RCH=NHimine
H2
RCH2NH2
1º-amine
(2) RCH=NH + RCH2NH2
imine 1º-amineRCH=NCH2R + NH3
substituted imine
H2 & catalyst
RCH2NHCH2R2º-amine
Complex Metal Hydride Reductions
The use of lithium aluminum hydride (LiAlH4) and sodium borohydride (NaBH4) as reagents for the reduction of aldehydes and ke-tones to 1º and 2º-alcohols respectively has been noted. Of these, lithium aluminum hydride, often abbreviated LAH, is the most useful for reducing carboxylic acid derivatives. Thanks to its high reactivity, LAH easily reduces all classes of carboxylic acid deriv-
10
3536
3738
11
atives, generally to the –1 oxidation state. Acids, esters, anhydrides and acyl chlorides are all reduced to 1º-alcohols, and this method is superior to catalytic reduction in most cases. Since acyl chlorides and anhydrides are expensive and time consuming to prepare, acids and esters are the most commonly used reactants for this transformation.Amides are reduced to amines by treatment with LAH, and this has proven to be one of the most general methods for preparing all classes of amines (1º, 2º & 3º). Because the outcome of LAH reduction is so different for esters and amides, we must examine plausible reaction mechanisms for these reactions to discover a reason for this divergent behavior. As in the reductions of aldehy-des and ketones, the first step in each case is believed to be the irreversible addition of hydride to the electrophilic carbonyl car-bon atom. This is shown in the following diagrams, with the hydride-donating moiety being written as AlH4
(–). All four hydrogens are potentially available to the reduction, but when carboxylic acids are reduced, one of the hydrides reacts with the acidic O–H to gen-erate hydrogen gas. Although the lithium is not shown, it will be present in the products as a cationic component of ionic salts.
One explanation of the different course taken by the reductions of esters and amides lies in the nature of the different hetero atom substituents on the carbonyl group (colored green in the diagram). Nitrogen is more basic than oxygen, and amide anions are poorer leaving groups than alkoxide anions. Furthermore, oxygen forms especially strong bonds to aluminum. Addition of hydride produces a tetrahedral intermediate, shown in brackets, which has a polar oxygen-aluminum bond. Neither the hydrogen nor the alkyl group (R) is a possible leaving group, so if this tetrahedral species is to undergo an elimination to reform a carbonyl group, one of the two remaining substituents must be lost. For the ester this is an easy choice (described by the curved arrows). By elimi-nating an aluminum alkoxide (R'O–Al), an aldehyde is formed, and this is quickly reduced to the salt of a 1º-alcohol by LAH. In the case of the amide, aldehyde formation requires the loss of an aluminum amide (R'2N–Al), an unlikely process. Alternatively, the more basic nitrogen may act to eject an aluminum oxide species (Al–O(–)), and the resulting iminium double bond would be reduced rapidly to an amine. This is the course followed in amide reductions.
Lithium aluminum hydride also reduces nitriles to 1º-amines, as shown in the following equation. An initial hydride addition to the electrophilic nitrile carbon atom generates the salt of an imine intermediate. This is followed by a second hydride transfer, and the resulting metal amine salt is hydrolyzed to a 1º-amine. This method provides a useful alternative to the catalytic reduction of ni-triles, described above, when alkene or alkyne functions are present.
In contrast to the usefulness of lithium aluminum hydride in reducing various carboxylic acid derivatives, sodium borohydride is sel-dom chosen for this purpose. First, NaBH4 is often used in hydroxylic solvents (water and alcohols), and these would react with acyl chlorides and anhydrides. Furthermore, it is sparingly soluble in relatively nonpolar solvents, particularly at low tempera-tures.Second, NaBH4 is much less reactive than LAH, failing to reduce amides and acids (they form carboxylate salts) at all, and reducing esters very slowly.Since relatively few methods exist for the reduction of carboxylic acid derivatives to aldehydes, it would be useful to modify the re-activity and solubility of LAH to permit partial reductions of this kind to be achieved. The most fruitful approach to this end has been to attach alkoxy or alkyl groups on the aluminum. This not only modifies the reactivity of the reagent as a hydride donor, but also in-creases its solubility in nonpolar solvents. Two such reagents will be mentioned here; the reactive hydride atom is colored blue.
Lithium tri-tert-butoxyaluminohydride (LtBAH), LiAl[OC(CH3)3]3H : Soluble in THF, diglyme & ether. Diisobutylaluminum hydride (DIBAH), [(CH3)2CHCH2]2AlH : Soluble in toluene, THF & ether.
Each of these reagents carries one equivalent of hydride. The first (LtBAH) is a complex metal hydride, but the second is simply an alkyl derivative of aluminum hydride. In practice, both reagents are used in equimolar amounts, and usually at temperatures well
11
3940
4142
12
below 0 ºC. The following examples illustrate how aldehydes may be prepared from carboxylic acid derivatives by careful applica-tion of these reagents. A temperature of -78 ºC is easily maintained by using dry-ice as a coolant. The reduced intermediates that lead to aldehydes will be displayed on clicking the "Show Intermediates" button. With excess reagent at temperatures above 0 ºC most carboxylic acid derivatives are reduced to alcohols or amines.
Back to the TopDiborane, B2H6
The reducing characteristics of diborane (disassociated to BH3 in ether or THF solution) were first introduced as addition reactions to alkenes and alkynes. This remains a primary application of this reagent, but it also effects rapid and complete reduction of carboxylic acids, amides and nitriles. Other than LAH, this reagent provides one of the best methods for reducing carboxylic acids to 1º-alcohols.
(1) R–CO2H + BH3
ether soln.[RCH2O–B]
H2O2
RCH2–OH
(2) R–C≡N + BH3
ether soln.RCH2–NH–B
H2ORCH2–NH2
Overview of Reducing Agents
The following table summarizes the influence each of the reducing systems discussed above has on the different classes of carboxylic acid deriv-atives. Note that LAH is the strongest reducing agent listed, and it reduces all the substrates. In a similar sense, acyl chlorides are the most reac-tive substrate. They are reduced by all the reagents, but only a few of these provide synthetically useful transformations.
FunctionReagent
Aldehydes& Ketones
CarboxylicAcids
CarboxylicEsters
AcylChlorides Amides Nitriles
H2
& catalystalcohols( slow, Pt, Pd )
(v. slow) (v. slow)aldehydes( Pd/BaSO4 )
(v. slow)amines( Ni cat. )
NaBH4
polar solvent alcohols N.R.
alcohols(slow)
complexmixture
N.R. N.R.
LiAlH4
ether or THFalcohols 1º-alcohol alcohols 1º-alcohol amines 1º-amine
LiAlH(Ot-Bu)3
1 eq. in THF alcohols(slow at 0º)
N.R. v. slowaldehyde(-78 º C)
aldehyde(-78 º C)
aldehyde(0 º C)
(iso-Bu)2AlH1 eq. in toluene
alcohols 1º-alcoholaldehyde(-78º C)
1º-alcoholaldehyde(-78 º C)
aldehyde(-78 º C)
B2H6
THFalcohols(slow)
1º-alcohol (v. slow)complexmixture
1º-amine 1º-amine
Color Code
12
4344
4546
13
Reduction occurs readily under normal conditions of temperature and pressure.
Reduction occurs readily, but selectivity requires low temperature.
Slow reduction occurs. Heating and/or high pressures of hydrogen are needed for effective use.
Reduction occurs very slowly or not at all (N.R.).
3. Reactions with Organometallic Reagents
The facile addition of alkyl lithium reagents and Grignard reagents to aldehydes and ketones has been described. These reagents, which are prepared from alkyl and aryl halides, are powerful nucleophiles and very strong bases. Reaction of an excess of these reagents with acyl chlorides, anhydrides and esters leads to alcohol products, in the same fashion as the hydride reduc-tions. As illustrated by the following equations (shaded box), this occurs by sequential addition-elimination-addition reactions, and finishes with hydrolysis of the resulting alkoxide salt. A common bonding pattern is found in all these carbonyl reactions. The organometallic reagent is a source of a nucleophilic alkyl or aryl group (colored purple), which bonds to the electrophilic carbon of the carbonyl group (colored orange). Substituent Y (colored green) is eliminated from the tetrahedral intermediate as its anion. The aldehyde or ketone product of this elimination then adds a second equivalent of the reagent.
Reactions of this kind are important synthetic transformations, because they permit simple starting compounds to be joined to form more complex structures. Esters are the most common carbonyl reactants, since they are cheaper and less hazardous to use than acyl chlorides and anhydrides. Most esters react with organometallic reagents to give 3º-alcohols; but formate esters (R=H) give 2º-alcohols. Some examples of these reactions are provided in the following diagram. As demonstrated by the last equation, lac-tones undergo ring opening and yield diol products.
The acidity of carboxylic acids and 1º & 2º-amides acts to convert Grignard and alkyl lithium reagents to hydrocarbons (see equa-tions), so these functional groups should be avoided when these reagents are used.
R–CO2H + R'–MgBrether soln.
R–CO2(–) MgBr(+) + R'–H
R–CONH2 + R'–Liether soln.
R–CONH(–) Li(+) + R'–H
Since acyl chlorides are more reactive than esters, isolation of the ketone intermediate formed in their reactions with organometallic reagents be-comes an attractive possibility. To achieve this selectivity we need to convert the highly reactive Grignard and lithium reagents to less nucle-ophilic species. Two such modifications that have proven effective are the Gilman reagent (R2CuLi) and organocadmium reagents (prepared in the manner shown).
2 R–MgBr + CdCl2ether & ben-zene R2Cd + MgBr2 + MgCl2
Specific examples of ketone synthesis using these reagents are presented in the following diagram. The second equation demon-strates the low reactivity of organocadmium reagents, inasmuch as the ester function is unchanged. Another related approach to
13
4748
4950
14
this transformation is illustrated by the third equation. Grignard reagents add to nitriles, forming a relatively stable imino derivative which can be hydrolyzed to a ketone. Imines themselves do not react with Grignard reagents.
4. Other Reactions
Amides are very polar, thanks to the n-π conjugation of the nitrogen non-bonded electron pair with the carbonyl group. This delo-calization substantially reduces the basicity of these compounds (pKa ca. –1) compared with amines (pKa ca. 11). When elec-trophiles bond to an amide, they do so at the oxygen atom in preference to the nitrogen. As shown below, the oxygen-bonded con-jugate acid is stabilized by resonance charge delocalization; whereas, the nitrogen-bonded analog is not. One practical application of this behavior lies in the dehydration of 1º-amides to nitriles by treatment with thionyl chloride. This reaction is also illustrated in the following diagram. Other dehydrating agents such as P2O5 effect the same transformation.
Reactivity of Carboxylic Acid Derivatives
Carboxylic acid derivatives react tend to react via nucleophilic acyl substitution where the group on the acyl unit, R-C=O under-goes substitution:
Study Tip: Note that unlike aldehydes and ketones , this reactivity of carboxylic acids retains the carbonyl group, C=O. .
The observed reactivity order is shown below:
This reactivity order is important. You should be able to understand, rationalise and use it.
14
5152
5354
15
It is useful to view the carboxylic acid derivatives as an acyl group, R-C=O, with a different substituent attached. The important features of the carboxylic acid derivatives that influence their reactivity are gov-erned by this substituent in the following ways:
the effect the substituent has on the electrophilicity of the carbonyl C . o if the substituent is electron donating, then the electrophilicity is reduced, \ less
reactive
o if the substituent is electron withdrawing, the the electrophilicity is increased, \more reactive
the ability of the substitutent to function as a leaving group.
Back to the TopThere are 3 resonance structures to consider for carboxylic acid derivatives.
I and II are similar to those of aldehydes and ketones, but there is also a third possibility III where a lone pair on the heteroatom Z is able to donate electrons to the adjacent positive center. The stronger this electron donation from Z the less positive the carbonyl C and the less electrophilic the carbonyl group. The ability of Z to donate electrons is linked to its electronegativity...the more elec-tronegative Z is, the less the stabilising effect.
Use the following series of electrostatic potential maps to look at the electrophilicity of the carbonyl C in a example of each the more common carboxylic acid derivatives. Note how the blue colour gradually reduces in intensity down the series.
The image shows the electrostatic potential for ethanoyl chlor-ide. The more red an area is, the higher the electron density and the more blue an area is, the lower the electron density.
The image shows the electrostatic potential for ethanoic anhyd-ride. The more red an area is, the higher the electron density and the more blue an area is, the lower the electron density.
The image shows the electrostatic potential for methyl eth-anoate. The more red an area is, the higher the electron density and the more blue an area is, the lower the electron density.
15
5556
5758
16
The image shows the electrostatic potential for ethanamide. The more red an area is, the higher the electron density and the more blue an area is, the lower the electron density.
The image shows the electrostatic potential for acetonitrile. The more red an area is, the higher the electron density and the more blue an area is, the lower the electron density.
Derivative Substituent Electronic Effect Leaving Group Ability Relative Reactivity
Acyl chloride -Cl withdrawing group (inductive) very good 1 (most)
Anhydride -OC=OR weakly donating good 2
Thioester -SR donating moderate 3
Ester -OR strongly donating poor =4
Acid -OH strongly donating poor =4
Amide -NH2, -NR2 very strongly donating very poor 5
Carboxylate -O- very, very strongly donating appalling ! 6 (least)
It is also useful to appreciate where aldehydes and ketones fit into the reactivity scale towards nucleophiles:
acyl halides > anhydrides > aldehydes > ketones > esters = carboxylic acids > amides
Overview of Nucleophilic Acyl Substitution Overall nucleophilic acyl substitution is most simply represented as follows:
What does the term "nucleophilic acyl substitution" imply ?
A nucleophile is an electron rich species that will react with an electron poor species (Nu in scheme). An acyl group is R-C=O (where R can be alkyl or aryl).... note the acyl group in both the starting material and the product. A substitution note that the leaving group (LG) is replaced by the nucleophile (Nu).
16
5960
6162
17
There are two fundamental events in a nucleophilic acyl substitution reaction:
formation of the new s bond to the nucleophile, Nu.
breaking of the s bond to the leaving group, LG.
Overall, these events are the same as those in a simple nucleophilic substitution , note the fundamental similarity in the two general pro-cesses.
The difference in nucleophilic acyl substitution is that when the nucleophile adds to the electrophilic C, it becomes tetrahedral and an intermediate forms, then the leaving group departs as shown below:
Back to the TopReactions for Interconverting Carboxylic Acids DerivativesHere is a table that summarises the methods for interconverting carboxylicacid derivatives. The more important reactions in em-phasised in bold,and the reactions of the parent carboxylic acids in blue.
To make ->
From
- RCO2- R'OH H2O R2NH H2O, HO-
- - R'OH H2O R2NH H2O, HO-
- -
R'OH, heat H+ or
B-
H2O, H3O+ R2NH H2O, HO-
heat
SOCl2
or PCl3
Heat, -H2O
R'OH, heat H+
- R2NH heat HO-
- - - H2O, H3O+ heat
- H2O, HO- heat
- RCOCl R'-Br or -I H3O+ - -
Reactions of Carboxylic Acid Derivatives17
6364
6566
18
Interconversion Reactions of Acyl Chlorides
acid anhyd-rides
esters
acids
amides
Reaction type: Nucleophilic Acyl Substitution
Summary
Acyl chlorides are the most reactive of the carboxylic acid derivativesand therefore can be readily converted into all other carboxylic acid derivatives(see above).
They are sufficiently reactive that they react quite readily with coldwater and hydrolyse to the carboxylic acid.
The HCl by-product is usually removed by adding a base such as pyridine,C6H5N, or triethyl amine, Et3N.
Interconversion Reactions of Acid Anhydrides
esters
acids
amides
Reaction type: Nucleophilic Acyl Substitution
Summary
Acid anhydrides are the second most reactive of the carboxylic acid derivatives and can therefore, be fairly readily converted into the other less reactive carboxylic acid derivatives (see above).
A base in often added to neutralise the carboxylic acid by product that is formed.
Back to the Top Interconversion Reactions of Esters
18
6768
6970
19
esters
acids
amides
Reaction type: Nucleophilic Acyl Substitution
Summary
Esters can be converted into other esters (transesterification), the parent carboxylic acid (hydrolysis) or amides (see above).
o Transesterification : heat with alcohol and acid catalyst
o Hydrolysis: heat with aq. acid o base (e.g. aq. H2SO4 or aq. NaOH) .
o Amide preparation : heat with the amine, methyl or ethyl esters are the most reactive
Interconversion Reactions of Amides
Reaction type: Nucleophilic Acyl Substitution
Summary
Amides are the least reactive of the neutral carboxylic acid derivatives.
The only interconversion reaction that amides undergo is hydrolysis back to the parent carboxylic acid and the amine.
Reagents : Strong acid (e.g. H2SO4) or strong base (e.g. NaOH) / heat.
More details on the following page.
Reactions of Nitriles
Reaction type: Nucleophilic Addition
Overview
Nitriles typically undergo nucleophilic addition to give products that often undergo a further reaction.
The chemistry of the nitrile functional group, C≡N, is very similar to that of the carbonyl, C=O of aldehydes and ketones. Compare the two schemes:
19
7172
7374
20
versus However, it is convenient to describe nitriles as carboxylic acid derivatives because:
o the oxidation state of the C is the same as that of the carboxylic acid derivatives.
o hydrolysis produces the carboxylic acid
Like the carbonyl containing compounds, nitriles react with nucleophiles via two scenarios:
Strong nucleophiles (anionic) add directly to the C≡N to form an intermediate imine salt that protonates (and often reacts further) on work-up with dilute acid.
Examples of such nucleophilic systems are : RMgX, RLi, RC≡CM, LiAlH4
Weaker nucleophiles (neutral) require that the C≡N be activated prior to attack of the Nu. This can be done using a acid catalyst which protonates on the Lewis basic N and makes the system more electrophilic.
Examples of such nucleophilic systems are : H2O, ROH
The protonation of a nitrile gives a structure that can be re-drawn in another resonance form that reveals the electrophilic character of the C since it is a carbocation.
Back to the TopFriedel-Crafts Acylation of Benzene
Reaction type: Electrophilic Aromatic Substitution
Summary
Overall transformation : Ar-H to Ar-COR(a ketone)
Named after Friedel and Crafts who discovered the reaction.
Reagent : normally the acyl halide (e.g. usually RCOCl) with aluminum trichloride, AlCl3, a Lewis acid catalyst
20
7576
7778
21
The AlCl3 enhances the electrophilicity of the acyl halide by complexing with the halide
Electrophilic species : the acyl cation or acylium ion (i.e. RCO + ) formed by the "removal" of the halide by the Lewis acid catalyst
The acylium ion is stabilised by resonance as shown below. This extra stability prevents the problems associated with the rearrange-ment of simple carbocations:
The reduction of acylation products can be used to give the equivalent of alkylation but avoids the problems of rearrangement (more details)
Friedel-Crafts reactions are limited to arenes as or more reactive than mono-halobenzenes
Other sources of acylium can also be used such as acid anhydrides with AlCl3
MECHANISM FOR THE FRIEDEL-CRAFTS ACYLATION OF BENZENE Step 1: The acyl halide reacts with the Lewis acid to form a a more electrophilic C, an acylium ionStep 2: The p electrons of the aromatic C=C act as a nucleophile, attacking the electrophilic C+. This step destroys the aromaticity giving the cyclohexadienyl cation intermediate.
Step 3: Removal of the proton from the sp3 C bearing the acyl- group reforms the C=C and the aromatic system, generating HCl and regenerating the active catalyst.
Back to the TopHydrolysis of Esters
Reaction type: Nucleophilic Acyl Substitution
Summary
Carboxylic esters hydrolyse to the parent carboxylic acid and an alcohol.
Reagents : aqueous acid (e.g. H2SO4) / heat,or aqueous NaOH / heat (known as "saponification").
These mechanisms are among some of the most studied in organic chemistry.
Both are based on the formation of a tetrahedral intermediate which then dissociates.
21
7980
8182
22
In both cases it is the C-O bond between the acyl group and the oxygen that is cleaved.
Reaction under BASIC conditions: The mechanism shown below leads to acyl-oxygen cleavage (see step2).
The mechanism is supported by experiments using 18O labeled compounds and esters of chiral alcohols.
This reaction is known as "saponification" because it is the basis of making soap from glycerol triesters in fats.
The mechanism is an example of the reactive system type.
MECHANISM OF THE BASE HYDROLYSIS OF ESTERS
Step 1:The hydroxide nucleophiles attacks at the electrophilic C ofthe ester C=O, breaking the bond and creating the tetrahedral intermediate.Step 2:The intermediate collapses, reforming the C=Oresults in the loss of the leaving group the alkoxide, RO-, leading to the carboxylic acid.Step 3:An acid / base reaction. A very rapid equilibrium where the alkoxide,RO- functions as a base deprotonating the carboxylic acid, RCO2H, (an acidic work up would allow the carboxylic acid to be obtained from the reaction).
Reaction under ACIDIC conditions:
Note that the acid catalysed mechanism is the reverse of the Fischer esterification.
The mechanism shown below also leads to acyl-oxygen cleavage (see step 5).
The mechanism is an example of the less reactive system type.
MECHANISM OF THE ACID CATALYSED HYDROLYSIS OF ESTERS Step 1:An acid/base reaction. Since we only have a weak nucleophile and a poor electrophile we need to activate the ester. Protonation of the ester carbonyl makes it more electrophilic.Step 2:The water O functions as the nucleophile attacking the electrophilic C in the C=O, with the electrons moving towards the oxonium ion, creating the tetrahedral intermediate.Step 3:An acid/base reaction. Deprotonate the oxygen that came from the water molecule to neutral-ise the charge.Step 4:An acid/base reaction. Need to make the -OCH3 leave, but need to convert it into a good leav-ing group first by protonation.Step 5:Use the electrons of an adjacent oxygen to help "push out" the leaving group, a neutral meth-anol molecule.Step 6:An acid/base reaction. Deprotonation of the oxonium ion reveals the carbonyl C=O in the carboxylic acid product and regenerates the acid catalyst.
22
8384
8586
23
Back to the TopPreparation of Esters
Reaction type: Nucleophilic Acyl Substiution
Summary
This reaction is also known as the Fischer esterification.
Esters are obtained by refluxing the parent carboxylic acid with the appropraite alcohol with an acid catalyst.
The equilibrium can be driven to completion by using an excess of either the alcohol or the carboxylic acid, or by removing the water as
23
8788
8990
24
it forms.
Alcohol reactivity order : CH3OH > 1o > 2o > 3o (steric effects)
Esters can also be made from other carboxylic acid derivatives, especially acyl halides and anhydrides, by reacting them with the ap-propriate alcohol in the presence of a weak base .
If a compound contains both hydroxy- and carboxylic acid groups, then cyclic esters or lactones can form via an intramolecular reac-tion. Reactions that form 5- or 6-membered rings are particularly favourable.
Study Tip: The carboxylic acid and alcohol combination used to prepare an ester are reflected by the name of the ester, e.g. ethyl acetate (or ethyl ethanoate), CH3CO2CH2CH3 can be made from CH3CO2H, acetic acid (or ethanoic acid) and HOCH2CH3 (ethanol). This general "disconnection" is shown below:
MECHANISM FOR REACTION FOR ACID CATALYSED ESTERIFICATION
Step 1: An acid/base reaction. Protonation of the carbonyl makes it more electrophilic.Step 2: The alcohol O functions as the nucleophile attacking the electrophilic C in the C=O, with the electrons moving towards the oxonium ion, creating the tetrahedral intermediate.Step 3: An acid/base reaction. Deprotonate the alcoholic oxygen.Step 4: An acid/base reaction. Need to make an -OH leave, it doesn't matter which one, so convert it into a good leaving group by protonation.Step 5: Use the electrons of an adjacent oxygen to help "push out" the leaving group, a neutral water molecule.Step 6: An acid/base reaction. Deprotonation of the oxonium ion reveals the carbonyl in the ester product.
24
9192
9394
25
Reduction of Esters
Reactions usually in Et2O or THF followed by H3O+work-ups
Reaction type: Nucleophilic Acyl Substitution then NucleophilicAddition
Back to the TopSummary
25
9596
9798
26
Carboxylic esters are reduced give 2 alcohols, one from the alcohol portion of the ester and a 1o alcohol from the reduction of the carboxylate portion.
Esters are less reactive towards Nu than aldehydes or ketones.
They can only be reduced by LiAlH4 but NOT by the less reactive NaBH4
The reaction requires that 2 hydrides (H-) be added to the carbonyl group of the ester
The mechanism is an example of the reactive system type.
The reaction proceeds via a aldehyde intermediate which then reacts with the second equivalent of the hydride reagent (review)
Since the aldehyde is more reactive than the ester, the reaction is not normally used as a preparation of aldehydes .
MECHANISM OF THE REACTION OF LiAlH4 WITH AN ESTER
Step 1: The nucleophilic H from the hydride reagent adds to the electrophilic C in the polar carbonyl group of the ester. Electrons from the C=O move to the electronegative O creating the tetra-hedral intermediate a metal alkoxide complex.Step 2: The tetrahedral intermediate collapses and displaces the alcohol portion of the ester as a leaving group, in the form of the alkoxide, RO-. This produces an aldehyde as an intermediate.Step 3: Now we are reducing an aldehyde (which we have already seen) The nucleophilic H from the hydride reagent adds to the electrophilic C in the polar carbonyl group of the aldehyde. Electrons from the C=O move to the electronegative O creating an in-termediate metal alkoxide complex.
Step 4: This is the work-up step, a simple acid/base reaction. Protonation of the alkoxide oxygen cre-ates the primary alcohol product from the intermediate complex.
Reactions of RLi and RMgX with Esters
Reaction usually in Et2O followed by H3O+ work-up
Reaction type: Nucleophilic Acyl Substitution then NucleophilicAddition
Summary
Carboxylic esters, R'CO2R'', react with 2 equivalents of organolithium or Grignard reagents to give tertiary alcohols.
The tertiary alcohol that results contains 2 identical alkyl groups (from R in the scheme)
The reaction proceeds via a ketone intermediate which then reacts with the second equivalent of the organometallic reagent .
Since the ketone is more reactive than the ester, the reaction cannot be used as a preparation of ketones.
The mechanism is an example of the reactive system type.
26
99100
101102
27
MECHANISM OF THE REACTION OF RMgX WITH AN ESTER
Step 1: The nucleophilic C in the organometallic reagent adds to theelectrophilic C in the polar carbonyl group of the ester. Electrons from the C=O move to the electronegative O cre-ating thetetrahderal intermediate, a metal alkoxide complex.Step 2: The tetrahedral intermediate collapses and displaces the alcohol portion of the ester as a leaving group, in the form of the alkoxide, RO-.This produces a ketone as an interme-diate.Step 3: The nucleophilic C in the organometallic reagent adds to the electrophilic C in the polar carbonyl group of the ketone. Electrons from the C=O move to the electronegative O creating an intermediate metal alkoxide complex.
Step 4: This is the work-up step, a simple acid/base reaction. Protonationof the alkoxide oxy-gen creates the alcohol product from the intermediate complex.
Hydrolysis of Amides
Reaction type: Nucleophilic Acyl Substitution
Summary
Amides hydrolyse to the parent carboxylic acid and the appropriate amine.
The mechanisms are similar to those of esters.
Reagents : Strong acid (e.g. H2SO4) / heat (preferred) or strong base (e.g. NaOH) / heat.
Reaction under ACIDIC conditions: Note that the acid catalysed mechanism is analogous to the acid catalysed hydrolysis of esters.
The mechanism shown below proceeds via protonation of the carbonyl not the amide N (see step 1).
The mechanism is an example of the less reactive system type.
MECHANISM OF THE ACID CATALYSED HYDROLYSIS OF AMIDES Step 1:An acid/base reaction. Since we only have a weak nucleophile and apoor electrophile we need to activate the amide. Protonation of the amidecarbonyl makes it more electrophilic.Step 2:The water O functions as the nucleophile attacking the electrophilicCin the C=O, with the elec-trons moving towards the oxonium ion, creatingthe tetrahedral intermediate.Step 3:An acid/base reaction. Deprotonate the oxygen that came from the watermolecule to neutralise the charge.
27
103104
105106
28
Step 4:An acid/base reaction. Need to make the -NH2leave, but need to convert it into a good leaving group first byprotonation.Step 5:Use the electrons of an adjacent oxygen to help "push out" the leavinggroup, a neutral ammo-nia molecule.Step 6:An acid/base reaction. Deprotonation of the oxonium ion reveals thecarbonyl in the carboxylic acid product and regenerates the acid catalyst.
Back to the TopReduction of Amides
Reactions usually in Et2O or THF followed by H3O+ work-ups
Reaction type: Nucleophilic Acyl Substitution then Nucleophilic Addition
Summary
Amides, RCONR'2, can be reduced to the amine, RCH2NR'2 by conversion of the C=O to -CH2-
Amides can be reduced by LiAlH4 but NOT the less reactive NaBH4
Typical reagents : LiAlH4 / ether solvent followedby aqueous work-up.
28
107108
109110
29
Note that this reaction is different to that of other C=Ocompounds which reduce to alcohols
The nature of the amine obtained depends on the substituents present onthe original amide. ook at the N substituents in the following examples (those bonds don'tchange !)
R, R' or R" may be either alkyl or aryl substituents.
In the potential mechanism note that it is an O system that leaves.This is consistent with O systems being better leaving groups thatthe less electronegative N systems.
MECHANISM OF THE REACTION OF LiAlH4 WITH AN AMIDE Step 1:The nucleophilic H from the hydride reagent adds to the electrophilic C in the polar carbonyl group of the ester. Electrons from the C=O move to the electronegative O creating the tetrahedral intermedi-ate, a metal alkoxide complex.Step 2:The tetrahedral intermediate collapses and displaces the O as part of a metal alkoxide leaving group, this produces a highly reactive iminium ion an intermediate.Step 3: Rapid reduction by the nucleophilic H from the hydride reagent as it adds to the electrophilic C in the iminium system. electrons from the C=N move to the cationic N neutralising the charge creating the amine product.
Hydrolysis of Nitriles
Reaction type: Nucleophilic Addition then NucleophilicAcyl Substitution
Summary
Nitriles, RC≡N, can be hydrolysedto carboxylic acids, RCO2H via the amide, RCONH2.
29
111112
113114
30
Reagents : Strong acid (e.g. H2SO4) or strongbase (e.g. NaOH) / heat.
MECHANISM OF THE ACID CATALYSED HYDROLYSIS OF NITRILES Step 1:An acid/base reaction. Since we only have a weak nucleophile so activate the nitrile, protonation makes it more electrophilic.Step 2:The water O functions as the nucleophile attacking the electrophilic C in the C≡N, with the electrons moving towards the positive center. Step 3:An acid/base reaction. Deprotonate the oxygen that came from the water molecule. The remaining task is a tautomerization at N and O centers. Step 4:An acid/base reaction. Protonate the N gives us the -NH2 we need.... Step 5:Use the electrons of an adjacent O to neutralise the positive at the N and form the bond in the C=O. Step 6:An acid/base reaction. Deprotonation of the oxonium ion reveals the carbonyl in the amide interme-diate....halfway to the acid.....
Back to the TopReduction of Nitriles
Reactions usually in Et2O or THF followed by H3O+work-up
Reaction type: Nucleophilic Addition
Summary
The nitrile, RC≡N, gives the 1o amine by conversion of the C≡N to -CH2-NH2
Nitriles can be reduced by LiAlH4 but NOT the less reactive NaBH4
Typical reagents : LiAlH4 / ether solvent followed by aqueous work-up.
30
115116
117118
31
Catalytic hydrogenation (H2 / catalyst) can also be used giving the same products.
R may be either alkyl or aryl substituents
Reactions of RLi or RMgX with Nitriles
Reaction usually in Et2O or THF
Reaction type: Nucleophilic Acyl Substitution then Nucleophilic Addition
Summary:
Nitriles, RC≡N, react with Grignard reagents or organolithium reagents to give ketones.
The strongly nucleophilic organometallic reagents add to the C≡N bond in a similar fashion to that seen for aldehydes and ketones.
The reaction proceeds via an imine salt intermediate that is then hydrolysed to give the ketone product.
Since the ketone is not formed until after the addition ofwater, the organometallic reagent does not get the opportunity to react with the ketone product.
Nitriles are less reactive than aldehydes and ketones.
The mechanism is an example of the reactive system type.
MECHANISM FOR THE REACTION OF RMgX WITH A NITRILE Step 1:The nucleophilic C in the organometallic reagent adds to theelectrophilic C in the polar nitrile group. Electrons from the C≡N move to the electronegative N creating an intermediate imine salt complex.Step 2:An acid/base reaction. On addition of aqueous acid, the intermediate salt proton-ates giving the imine.Step 3:An acid/base reaction. Imines undergo nucleophilic addition, but require activation by protonation (i.e. acid catalysis).Step 4:Now the nucleophilic O of a water molecule attacks the electrophilicCwith the bond breaking to neutralise the change on the N. Step 5:An acid/base reaction. Deprotonate the O from the water molecule to neutralise the positive charge.Step 6:An acid/base reaction. Before the N system leaves, it needs to be made into a better leaving group by protonation.Step 7:Use the electrons on the O in order to push out the N leaving group, a neutral mo-lecule of ammonia. Step 8:An acid/base reaction. Deprotonation reveals the carbonyl group ofthe ketone product.
31
119120
121122
32
Back to the TopSpectroscopic Analysis
Spectroscopic Analysis of Acyl Chlorides
IR - presence of high frequency C=O, C-Cl too low to be useful
Absorbance (cm-1) Interpretation
1800 C=O stretch
1H NMR - only the protons adjacent to the C=O are particularly characteristic.
Resonance (ppm) Interpretation
~2 - 2.5 H-C-C=O
32
123124
125126
33
13C NMR
C=O typically 160-180 ppm (deshielding due to O)
o minimal intensity, characteristic of C's with no attached H's
UV-VIS two absorption maxima p→p* (<200 nm) n→p* (~235 nm)
o p electron from p of C=O
o n electron from O lone pair
o p* antibonding C=O
Mass Spectrometry Prominent peak corresponds to formation of acyl cations (acylium ions)
Spectroscopic Analysis of Anhydrides
IR - presence of two, high frequency C=O
Absorbance (cm-1) Interpretation
1820 C=O stretch
1750 C=O stretch
1H NMR - only the protons adjacent to the C=O are particularly characteristic.
Resonance (ppm) Interpretation
~2 - 2.5 H-CC=O
13C NMR
C=O typically 160-180 ppm (deshielding due to O)
o minimal intensity, characteristic of C's with no attached H's
UV-VIS two absorption maxima p→p* (<200 nm) n→p* (~225nm, diagnostic)
o p electron from p of C=O
o n electron from O lone pair
o p* antibonding C=O
Mass Spectrometry Prominent peak corresponds to formation of acyl cations (acylium ions)
Back to the TopSpectroscopic Analysis of Esters
IR - presence of C=O, and two C-O bands (Csp2-O and Csp3-O bonds)
33
127128
129130
34
Absorbance (cm-1) Interpretation
1735 C=O stretch
1300-1000 two bands for C-O stretch
1H NMR - deshielded proton of H-C-O is often recognisable, and H-C-C=O.
Resonance (ppm) Interpretation
3.5-4.5 H-COC
2-2.5 H-C-C=O
13C NMR
C=O typically 160-180 ppm (deshielding due to O)
o minimal intensity, characteristic of C's with no attached H's
UV-VIS two absorption maxima p→p* (<200 nm) n→p* (~207 nm)
o p electron from p of C=O
o n electron from O lone pair
o p* antibonding C=O
Mass Spectrometry Prominent peak corresponds to formation of acyl cations (acylium ions)
Spectroscopic Analysis of Amides
IR - presence of low frequency C=O, N-H stretches for 1o or 2o amides.
Absorbance (cm-1) Interpretation
1660 C=O stretch
3500 and 3100 N-H stretch (two for NH2, one for NH)
1H NMR - N-H protons often broad,
Resonance (ppm) Interpretation
5-8 (broad, exchangeable) NH
~ 2 - 2.4 H-C-C=O
13C NMR
C=O typically 160-180 ppm (deshielding due to O)
o minimal intensity, characteristic of C's with no attached H's
UV-VIS absorption maxima n→p* (~215 nm)
o n electron from O lone pair
o p* antibonding C=O
34
131132
133134
35
Mass Spectrometry Molecular ion M+ often visible. A prominent peak corresponds to formation of acyl cations (acylium ions)
Spectroscopic Analysis of Nitriles
IR - very characteristic C≡N stretch (only C≡C is similar region)
Absorbance (cm-1) Interpretation
2250 C≡N stretch
1H NMR - only protons adjacent to C≡N are likely to be characterisitic.
Resonance (ppm) Interpretation
> 2 - 3
H-C-C≡N
13C NMR
C≡N typically 115 -125 ppm (deshielding due to N)
o minimal intensity, characteristic of C's with no attached H's
UV-VIS Simple nitriles usually show no absorption above 200 nm.
Mass Spectrometry
Molecular ion M+ is often weak or absent, but a weak M-1 peak due to loss of an a-H is often present.
Back to the Top Alcohols
Alde-hydes & Ketones
Alkyl Halide Re-action
Go to Main Menu
35
135136
137138
36
© M.EL-Fellah ,Chemistry Department, Garyounis University
36
139140
5
141142