Carboxylic Acids

Question 1

Define:

Carboxylic Acid

Answer 1

A carboxylic acid is an organic acid that contains a carboxyl (-COOH) group.

Carboxylic acids have IUPAC names that end in “-oic acid” (i.e. propanoic acid).

Question 2

Which of the following acids (top or bottom) is a carboxylic acid?

Answer 2

The top acid is a carboxylic acid due to the presence of a carboxyl (-COOH) group.

An acid must contain at least one carboxyl group in order to be classified as a carboxylic acid.

Question 3

Which of the following acids is a carboxylic acid?

• Phosphoric acid
• Benzenesulfonic acid
• Pentanoic acid

Answer 3

Pentanoic acid is a carboxylic acid.

Carboxylic acids are named by converting the IUPAC name of the base chain, and adding the suffix “-oic acid.” Pentanoic acid consists of a five carbon chain (pentane) that contains a carboxyl group (oic acid).

Question 4

What is the IUPAC name of this molecule?

Answer 4

This molecule is named ethanoic acid.

Carboxylic acids are named by converting the IUPAC name of the base chain, and adding the suffix “-oic acid.” Ethanoic acid is commonly known as acetic acid.

Question 5

What is the IUPAC name of this molecule?

Answer 5

This molecule is named ethanedioic acid.

Dicarboxylic acids are named by adding the suffix of “-dioic acid” to the IUPAC name, to indicate that two carboxyl groups are attached. Ethanedioic acid is commonly known as oxalic acid.

Question 6

What is the IUPAC name of this molecule?

Answer 6

This molecule is named benzoic acid.

Carboxylic acids are typically named by dropping the “e” from the IUPAC alkane that contains the carboxyl group and adding the suffix of “-oic acid.” In this case the benzene ring is the base.

Question 7

How do the boiling points of carboxylic acids compare to the boiling points of other types of molecules with similar mass and branching?

Answer 7

Carboxylic acids tend to have higher boiling points relative to other molecules of similar mass and branching.

Carboxylic acids contain O-H groups that allow them to form hydrogen bonds, resulting in high boiling points. Hydrogen bonding is a stronger force than dipole-dipole or dispersion forces.

Question 8

Why do carboxylic acids have high boiling points compared to other similar sized acids?

Answer 8

Carboxylic acids can form hydrogen bonds with each other, resulting in higher relative boiling points than other acids without the ability to hydrogen bond.

Carboxylic acids can form two hydrogen bonds, one from the polar C=O group to a new hydrogen and one from the O-H group, resulting in the formation of cyclic dimers and very high boiling points.

Question 9

Rank the following from highest to lowest BP:

• Butanone
• Butanol
• Butanoic acid
• Butane

Answer 9

Butanoic acid > butanol > butanone > butane

Butanoic acid is able to form dimers (a double hydrogen bond pair) and has the highest boiling point. Hydrogen bonding in butanol is stronger than the dipole-dipole in butanone. And butane has only dispersion forces.

Question 10

Define:

Hydrogen bonding

Answer 10

Hydrogen bonding is the strongest dipole-dipole interaction between molecules that contain hydrogen bound to highly electronegative atoms (F, O, N).

Carboxylic acids contain O-H bonds and are able to participate in hydrogen bonding, including the formation of dimers.

Question 11

Define:

Dimer

Answer 11

A dimer is a pair of two structurally similar molecules linked together by chemical bonds.

For the MCAT, dimers are most commonly carboxylic acids linked together by hydrogen bonds.

Question 12

What features of carboxylic acids allow for dimerization to occur between two molecules?

Answer 12

Carboxylic acids contain O-H bonds and are able to form two hydrogen bonds between molecules.

Dimerization is usually only tested on the MCAT when discussing a homogeneous carboxylic acid. Technically, if water is mixed in, hydrogen bonds can instead form between water and the acid molecules.

Question 13

What would it look like if acetic acid (ethanoic acid) molecules came together as a dimer?

Answer 13

Acetic acid molecules would form a homodimer linked by two hydrogen bonds.

A homodimer implies that both molecules are the same substance. It’s possible to form heterodimers between different carboxylic acids, though this is rarely tested on the MCAT.

Question 14

What would the dimer look like if benzoic acid molecules came together?

Answer 14

Benzoic acid molecules would form a homodimer linked by two hydrogen bonds.

A homodimer implies that both molecules are the same substance. It’s possible to form heterodimers between different carboxylic acids, though this is rarely tested on the MCAT.

Question 15

In what type of solvent are carboxylic acids most soluble?

Answer 15

Carboxylic acids are most soluble in polar protic solvents.

Recall: “like dissolves like” and carboxylic acids are highly polar due to the presence of the carboxyl group and can form hydrogen bonds.

Question 16

Which of the following solvents will a carboxylic acid dissolve in most readily?

• Water
• Ethane
• Cyclohexane

Answer 16

A simple carboxylic acid will dissolve most readily in water, a polar solvent that forms hydrogen bonds.

Recall: “like dissolves like”.

Question 17

How is the acidity of a carboxylic acid affected by the inductive effects of subtituents?

Answer 17

Acidity will increase if substituent groups can withdraw electron density through induction and delocalize the negative charge of the carboxyl group.

Electron-donating groups will decrease the acidity, since they destabilize the carboxyl group.

Question 18

Which of the following (top or bottom) is a better acid, and why?

Answer 18

The bottom acid (acetic acid) is a better acid.

The additional alkyl group of the top acid (propanoic acid) is electron-donating and destabilizes the negative charge of the carboxylate ion.

Question 19

How does resonance contribute to the acidity of a carboxylic acid?

Answer 19

Resonance allows the negative charge of the carboxylate ion to be delocalized/stabilized between the oxygen atoms of the carboxyl group.

Each oxygen atom receives a partial negative charge, and a resonance 1.5 bond strength to the central carbon.

Question 20

Which of the following two molecules (top or bottom) is a better acid, and why?

Answer 20

The top (carboxylic acid) is much more acidic than the bottom (alcohol) due to the resonance stabilization of the carboxylate ion.

Resonance delocalizes the negative charge and increases acidity. An alcohol should also have relatively low acidity in general.

Question 21

How does the number of electron withdrawing groups affect the acidity of a carboxylic acid?

Answer 21

The more electron withdrawing groups, the stronger acidity of the acid.

Additional electron-donating groups, in contrast, will decrease the acidity.

Question 22

Which of the following two groups is a better acid, and why?

Answer 22

The carboxylic acid with two chlorine substituents is a better acid because the additional electron-withdrawing group increases the stability of the carboxylate ion.

Question 23

Which of the following two groups is a better acid, and why?

Answer 23

The carboxylic acid with fewer alkyl substituents (isobutyric acid) is a better acid because it has fewer electron-donating groups.

Additional electron-donating groups decrease the stability of the carboxylate ion.

Question 24

How is the acidity of a carboxylic acid affected by the electronegativy of substituent groups?

Answer 24

More electronegativity (electron-withdrawing groups) on carbon atoms adjacent to a carboxyl group will increase acidity.

The more electronegative a substituent is, the more delocalization of the negative charge on the carboxyl group, resulting in a stronger acid.

Question 25

Which of the following (top or bottom) is a better acid, and why?

Answer 25

The top acid containing chlorine (chloroacetic acid) is a better acid. Chlorine is more electronegative and better able to delocalize the negative charge of the carboxylate ion than bromine.

Question 26

Which of the following (top or bottom) is a better acid, and why?

Answer 26

The top acid containing fluorine (fluoroacetic acid) is a better acid. Fluorine is more electronegative and better able to delocalize the negative charge of the carboxylate ion than chlorine.

Question 27

How does the distance of an electron-withdrawing group from the carboxyl carbon affect the acidity of a carboxylic acid?

Answer 27

A carboxylic acid with an electron-withdrawing group further from the carboxyl carbon will be less acidic than one with a closer electron-withdrawing group.

Inductive effects of both electron-donating and electron-withdrawing substituents decrease with distance.

Question 28

Which of the following carboxylic acids (top or bottom) is a better acid, and why?

Answer 28

The top acid is a better acid due to the closer electron-withdrawing group.

The inductive effects of electron-withdrawing groups decrease with distance. A group on the alpha carbon will have a greater effect than one on the beta carbon.

Question 29

How is charge distributed in a carboxyl group?

Answer 29

The oxygens are partially negatively charged and the carbon is partially positively charged.

Question 30

If a reaction is ocurring, what type of reaction component could the carbon atom in a carboxyl group be?

Answer 30

The carbon atom of a carboxyl group most frequently plays the role of an electrophile in a reaction.

Electrophiles are usually positively charged, or electron-deficient, and receive electrons in a reaction.

Question 31

If a reaction is ocurring, what type of reaction component could the oxygen atoms in a carboxyl group be?

Answer 31

The oxygen atoms of a carboxyl group most frequently play the role of a nucleophile in a reaction.

Nucleophiles are usually negatively charged, or electron-rich, and donate electrons in a reaction.

Question 32

What feature of a carboxylic acid allows for the reactivity of the alpha carbon?

Answer 32

Reactivity is present at the alpha carbon due to the ability of the acid to form an enol and enolate ion.

Carboxylic acids often require conversion to an enolizable form before reactions at the alpha carbon can occur.

Question 33

How does nucleophilic attack most commonly occur on a carboxylic acid?

Answer 33

The nucleophile attacks the carbon atom of the carboxyl group, producing an intermediate with negative charge on the carbonyl oxygen.

The lowest energy final state is nucleophilic substitution, which includes the reformation of the carbonyl double bond and the elimination of a leaving group.

Question 34

What intermediate would most likely be formed by a nucleophile attack on the following carboxylic acid?

Answer 34

The nucleophile would attack the electron-deficient carbon atom of the carboxyl group.

This type of attack and intermediate is formed in many reactions with carboxylic acids, including reduction, ester formation, and acyl halide formation.

Question 35

Define:

α-**Halogenation **

Answer 35

α-Halogenation is the substituion of a halide atom for a hydrogen at the alpha carbon of a carboxylic acid.

The reaction is known as the HVZ reaction and commonly involves Br₂ and PCl₃ or PBR₃ in catalytic amounts. It proceeds through the formation of an acid bromide enol.

Question 36

What is the product of the α-halogenation of the following carboxylic acid with bromine?

Answer 36

The bromine replaces a hydrogen at the alpha carbon of the carboxylic acid in a substitution reaction.

An acid bromide intermediate is produced and converted to its enol form, which reacts with bromine.

Question 37

Through which mechanism do most substitution reactions of carboxylic acids occur?

Answer 37

Most substitution reactions of carboxylic acids occur through nucleophilic acyl substitution.

In nucleophilic acyl substitution, the nucleophile attacks the carbon of the carboxyl group and replaces the leaving group (hydroxyl group for a carboxylic acid) in a substitution reaction,

Question 38

What is the product of the nucleophilic acyl substituion involving the following carboxylic acid and thionyl chloride (SOCl₂)?

Answer 38

The carboxylic acid (ethanoic acid) is converted to an acyl chloride (acetyl chloride).

Acyl chlorides are very reactive carboxylic acid derivatives that are useful for the synthesis of other, less reactive derivatives.

Question 39

What type of molecule is formed by the strong reduction of a carboxylic acid?

Answer 39

Carboxylic acids are reduced to form a corresponding primary alcohol by strong reducers.

Common strong reducers on the MCAT are NaBH₄ and LiAlH_4.

Question 40

What is the product of the reduction of the following carboxylic acid with LiAlH₄?

Answer 40

The carboxylic acid (isobutanoic acid) is reduced to a primary alcohol (isobutanol).

Question 41

Define:

Decarboxylation

Answer 41

Decarboxylation is the loss of a CO₂ molecule when the carboxyl group is effectively removed from a carboxylic acid.

When carboxylic acids undergo decarboxylation reactions, the number of carbon atoms is decreased by one and the residual H attaches where the original carbon was.

Question 42

What is the product when the following carboxylic acid undergoes a decarboxylation reaction?

Answer 42

Benzoic acid undergoes decarboxylation to form benzene.

As with all decarboxylation reactions, there is the loss of CO₂ from the molecule.

Question 43

What is the product when the following carboxylic acid undergoes a decarboxylation reaction?

Answer 43

The product will have a CO₂ removed from the molecule, and the NH₂ group will flex into that open space.

This reaction happens to also have biological significance, as it is the decarboxylation of tryptophan to form tryptomine.

Question 44

What is the product when the following carboxylate ion (pyruvate) undergoes a decarboxylation reaction in the presence of HS-CoA?

Answer 44

Pyruvate undergoes enzyme-catalyzed oxidative decarboxylation with the addition of HS-CoA to produce acetyl-CoA.

This happens during the second stage of aerobic cellular respiration in the Krebs cycle.

Question 45

Define:

Esterification

Answer 45

Esterification is the synthesis of an ester from a carboxylic acid and an alcohol in a dehydration reaction.

The reaction is commonly carried out by heating the carboxylic acid and alcohol in the presence of an acid catalyst.

Question 46

How are esters named in the IUPAC convention?

Answer 46

Esters are named by removing the suffixes from each group, and ending the chain from the alcohol substituent with “-yl”, and ending the carboxylic acid substituent with “-oate.”

A common ester on the MCAT is ethyl ethanoate, which would be formed from ethanol and a ethanoic acid.

Question 47

Assume that these two molecules react to form an ester, what would it look like and what is its IUPAC name?

Answer 47

The ester is called methyl ethanoate, from the methanol and ethanoic acid parent groups.

Note: the dehydration reactions creating esters should show a water molecule being removed.

Question 48

Assume that these two molecules react to form an ester, what would it look like and what is its IUPAC name?

Answer 48

The ester is called ethyl propanoate, from the ethanol and propanoic acid parent groups.

Note: the dehydration reactions creating esters should show a water molecule being removed.

Question 49

If an alcohol and carboxylic acid are combined in solution and heated, what reaction is expected to occur and what are the products?

Answer 49

An esterification reaction will ocurr between the alcohol and carboxylic acid. The expected product will be an ester and water.

Esterification reactions are commonly conducted by additionally having an acid catalyst.