You should know by now about some of the ways that carboxylic acids react (see Reactions of Carboxylic Acids for more information). In fact, they readily react like typical acids - they neutralise bases and form salts with metals or ammonia.
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Jetzt kostenlos anmeldenYou should know by now about some of the ways that carboxylic acids react (see Reactions of Carboxylic Acids for more information). In fact, they readily react like typical acids - they neutralise bases and form salts with metals or ammonia.
However, carboxylic acids don’t really take part in many other reactions. This is because they contain the hydroxyl functional group, -OH. This particular group, -OH, is a very poor leaving group. It isn’t stable on its own and prefers to be part of another molecule, such as a carboxylic acid. However, the close cousins of carboxylic acids, known as acid derivatives, react much more readily with a variety of substances - including in acylation reactions.
An acylation reaction is a reaction that involves adding the acyl group to another molecule.
In acylation reactions, we introduce the acyl group, -RCO-, to another molecule. The acyl group comes from a molecule known as an acylating agent, and the most common acylating agents are acyl chlorides and acid anhydrides. Both acyl chlorides and acid anhydrides are examples of acid derivatives.
Acid Derivatives are molecules that originate from Carboxylic Acids. They all contain the acyl group, -RCO-, and have the general structure RCOZ.
If you take a carboxylic acid and swap the hydroxyl (-OH) group for a chlorine atom, you end up with an acyl chloride. They have the general structure RCOCl. Their Z group is a chlorine atom.
On the other hand, if you take two carboxylic acids and join them together using an oxygen atom from one of their hydroxyl groups (releasing water in the process), you end up with an acid anhydride. They have the general structure RCOOCOR'.
You can think of acid anhydrides as having two acyl functional groups, but for the purpose of these reactions, it is much easier to consider the -OCOR' group as their Z group.
For your exams, you only have to know about acylation reactions with a symmetrical anhydride - one made from two molecules of the same carboxylic acid. This means that their two R groups, R and R', are the same. We can represent the molecule using (RCO)2O.
Check out Acid Derivatives for more about both acyl chlorides and acid anhydrides.
In this article, we'll focus on how acid derivatives react in two different types of acylation reactions:
To start, let's focus on nucleophilic addition-elimination acylation. These reactions involve acid derivatives and a specific nucleophile: either water, a primary alcohol, ammonia, or a primary amine.
Acid derivatives are polar molecules. They contain a partially negatively-charged oxygen atom and a partially positively-charged carbon atom:
This means that acid derivatives can be attacked by nucleophiles.
A nucleophile is an electron pair donor, containing a lone pair of electrons and a negative or partially negative charge.
Some common nucleophiles are water, alcohols, ammonia, and primary amines. As nucleophiles, they are attracted to areas of electron deficiency. In this case, they are attracted to the acid derivative’s partially positively-charged carbon atom, and they react in a nucleophilic addition-elimination acylation reaction. This has a two-step mechanism:
Overall, one of the nucleophile's hydrogen atoms is swapped for the acid derivative's acyl groups.
Let's now look at examples of nucleophilic addition-elimination reactions with each of these nucleophiles. We'll see how they react with both acyl chlorides and acid anhydrides and will learn about the mechanism and products of each reaction.
The first set of reactions we’ll look at involve water as the nucleophile.
To start with, let’s take a look at the reaction between an acyl chloride and water. This is probably the simplest of the nucleophilic addition-elimination acylation reactions and shows you the reaction’s general mechanism. It produces a carboxylic acid (RCOOH) and hydrochloric acid (HCl).
Here's the overall equation:
\(RCOCl+H_2O\rightarrow RCOOH+HCl\)
Acid anhydrides are produced using an elimination reaction between two carboxylic acids. Reacting an acid anhydride with water in a nucleophilic addition-elimination reaction is simply the reverse - it reforms both carboxylic acid molecules.
Here's the general equation:
\((RCO)_2O+H_2O\rightarrow 2RCOOH\)
For example, reacting ethanoic anhydride with water produces two molecules of ethanoic acid.
Once again, here's the equation:
\((CH_3CO)_2O+H_2O\rightarrow 2CH_3COOH\)
Most exam boards don’t require you to know the mechanism for this reaction, but make sure you check yours - you don’t want to get caught out!
The acylation reaction between acid derivatives and a primary alcohol is very similar to their reaction with water. When drawing your mechanism, simply replace one of the hydrogen atoms on the water molecule with an alkyl group. This reaction also occurs with phenol.
Reacting a primary alcohol with an acyl chloride produces an ester (RCOOR') and hydrochloric acid (HCl). Here's the equation:
\(RCOCl+R'OH\rightarrow RCOOR'+HCl\)
Let’s take ethanoyl chloride and methanol as an example. The reaction produces hydrochloric acid and methyl ethanoate (CH3COOCH3).
Notice that when naming these esters, the first part of the name comes from the alcohol nucleophile, whilst the second part comes from the acid derivative.
Reacting acid anhydrides with a primary alcohol produces an ester and a carboxylic acid:
\((RCO)_2O+R'OH\rightarrow RCOOR'+RCOOH\)
For example, when we react ethanoic anhydride with methanol, we also get methyl ethanoate. However, the second product is a carboxylic acid based on the acid anhydride. Here we get ethanoic acid (CH3COOH):
\((CH_3CO)_2O+CH_3OH\rightarrow CH_3COOCH_3+CH_3COOH\)
Reacting acid derivatives with ammonia produces an amide and an ammonium salt. This uses the same mechanism as the two reactions above, but there is an additional step involving an additional molecule of ammonia.
Reacting ammonia with an acyl chloride produces an amide and hydrochloric acid. However, the hydrochloric acid then reacts with an additional molecule of ammonia to produce ammonium chloride (NH4Cl):
\(RCOCl+2NH_3\rightarrow RCONH_2+NH_4Cl\)
Look at the reaction between ethanoyl chloride and ammonia. The initial reaction produces ethanamide (CH3CONH2) and hydrochloric acid; the hydrochloric acid reacts further with another ammonia molecule to produce ammonium chloride.
The overall reaction is between ethanoyl chloride and two ammonia molecules, producing ethanamide and ammonium chloride.
The other product of this reaction is what we call an amide. An amide is an organic molecule that contains the amine group (NH2) next to the carbonyl group (C=O).
Amides have their own dedicated article (check out Amides for more). We'd recommend that you check it out if you aren't sure how to name amides, as it will make these next few reactions a lot easier to understand!
If we react an acid anhydride with an excess of ammonia, we again produce an amide. The initial reaction also produces a carboxylic acid. However, a second molecule of ammonia reacts with the carboxylic acid to produce an ammonium salt.
Here's the equation:
\((RCO)_2O+2NH_3\rightarrow RCONH_2+RCOONH_4\)
For example, the reaction between ethanoic anhydride and ammonia produces ethanamide (CH3CONH2) and ammonium ethanoate (CH3COONH4):
\((CH_3CO)_2O+2NH_3\rightarrow CH_3CONH_2+CH_3COONH_4\)
A lot of new information has been thrown at you, but we just need to look at one more type of nucleophilic addition-elimination acylation reaction: reacting acid derivatives with primary amines. This is very similar to their reactions with ammonia - when you are drawing the mechanism, simply replace one of ammonia’s hydrogen atoms with an R group.
The reaction produces an N-substituted amide and a different ammonium salt.
If you react an acyl chloride with a primary amine, you produce an N-substituted amide and an ammonium salt:
\(RCOCl+2NH_2R'\rightarrow RCONHR'+R'NH_3Cl\)
Reacting propanoyl chloride (CH3CH2COCl) with methylamine (NH2CH3) gives N-methylpropanamide (CH3CH2CONHCH3) and methylammonium chloride (CH3NH3Cl):
\(CH_3CH_2COCl+2NH_2CH_3\rightarrow CH_3CH_2CONHCH_3+CH_3NH_3Cl\)
There are a lot of different R groups and carbon chains involved in this reaction, and so we've highlighted them in the diagram below to help you understand the process a little better.
If you react an acid anhydride with a primary amine, you produce an N-substituted amide and a different ammonium salt:
\((RCO)_2O+2NH_2R'\rightarrow RCONHR'+R'NH_3OCOR\)
Reacting propanoic anhydride ( (CH3CH2CO)2O) with methylamine produces N-methylpropanamide too. The initial reaction also produces a carboxylic acid based on the acid derivative. Because we started with propanoic anhydride, we produce propanoic acid. This then reacts with another molecule of methylamine to produce a different ammonium salt. Here we produce methylammonium propanoate (CH3NH3OCOCH2CH3):
\((CH_3CH_2CO)_2O+2NH_2CH_3\rightarrow CH_3CH_2CONHCH_3+CH_3NH_3OCOCH_2CH_3\)
Phew - you made it!
The following table should help consolidate your newfound knowledge of nucleophilic addition-elimination acylation reactions. SImply choose an acid derivative and a nucleophile, and read across the table to find your products.
Nucleophile | Acyl chloride | Acid anhydride | ||
Products | Conditions | Products | Conditions | |
Water | Carboxylic acidHydrochloric acid | Room temperature | Carboxylic acid | Heat |
Primary alcohol (including phenol) | EsterHydrochloric acid | EsterCarboxylic acid | ||
Ammonia | AmideAmmonium chloride | AmideAmmonium salt | ||
Primary amine | N-substituted amideAmmonium salt | N-substituted amideAmmonium salt |
Remembering all the different nucleophilic addition-elimination reactions can be tricky. However, they all follow similar mechanisms. Instead of trying to remember each reaction individually, learn how to apply a few examples to a variety of different combinations of reactants.
Some nucleophilic addition-elimination acylation reactions happen much faster than others. This is due to many different factors.
As we explored above, the carbon atom in the acid derivative that is joined to the oxygen atom and the Z group is partially negatively charged. The strength of this partial charge varies, depending on how electronegative the Z group is. A more electronegative Z group will attract the shared pair of electrons more strongly towards itself, increasing the carbon atom’s partial positive charge.
Imagine a tug of war between you and your friend. A piece of fabric tied around the middle of the rope represents the shared pair of electrons involved in the covalent bond between the two of you. If you are a lot stronger than your friend, you’ll be able to pull the rope and the fabric towards you. You have attracted the electrons towards yourself. We can say you are more electronegative than your friend. This leaves your friend electron-deficient and therefore partially positively charged. A carbon atom with a higher charge will be attacked by nucleophiles a lot more easily, as nucleophiles are negatively or partially negatively charged.
Some Z groups are better leaving groups than others. This increases their reactivity. We won’t go into the reasons here, but it involves things like electronegativity, size, and resonance. However, you should know that chloride ions are a much better leaving group than carboxylate ions, so acyl chlorides are more reactive than acid anhydrides. For example, all of the nucleophilic addition-elimination reactions involving acyl chlorides take place at room temperature and are extremely exothermic, whilst those involving acid anhydrides must be heated gently.
Stronger nucleophiles will attack the acid derivative’s partially charged carbon atom more readily than weaker nucleophiles. Again, this is due to factors that we won’t go into right now, but which include charge and basicity.
We have explored reactions between acid derivatives and four different nucleophiles. These nucleophiles all vary in strength. Their relative strengths are given below:
primary amine > ammonia > primary alcohol > water
Acylation reactions involving a primary amine therefore happen a lot faster than those involving water.
Do you remember how we said that there are two types of acylation reactions? The second is known as Friedel-Crafts acylation. It is used to add the acyl group to aromatic molecules such as benzene.
Like in nucleophilic addition-elimination acylation reactions, Friedel-Crafts acylation involves acid derivatives. But this reaction differs because it uses an electrophilic substitution mechanism. It also uses a catalyst, aluminium(III) chloride (AlCl3).
The overall reaction has multiple steps:
The products depend on the acid derivative used. We always produce an aromatic ketone with the structure C6H5COR; we name these molecules using the prefix phenyl-. We also produce the molecule HZ, where Z is the acid derivative's Z group. This means that if our acid derivative is an acyl chloride, we also produce hydrochloric acid (HCl). However, if our acid derivative is an acid anhydride, we also produce a carboxylic acid (RCOOH).
For example, if you react benzene with ethanoyl chloride (CH3COCl) in the presence of an aluminium(III) chloride catalyst, you produce phenylethanone (C6H5COCH3) and hydrochloric acid. If you react benzene with ethanoic anhydride ((CH3CO)2O), you also produce phenylethanone, but instead of hydrochloric acid you produce ethanoic acid (CH3COOH).
\(C_6H_6+CH_3COCl\rightarrow C_6H_5COCH_3+HCl\)
\(C_6H_6+(CH_3CO)_2O\rightarrow C_6H_5COCH_3+CH_3COOH\)
Head over to Reactions of Benzene to discover more about Friedel-Crafts acylation. If you want to know the mechanism for this reaction, you'll find it in the article Benzene Electrophilic Substitution.
We'll now consider some of the uses of acylation.
First of all, you’ll notice that reacting acyl chlorides or acid anhydrides with an alcohol produces an ester. We can also make esters by reacting a carboxylic acid with an alcohol in an esterification reaction. This is reversible, whereas acylation goes to completion. Therefore, acylation is often preferred to esterification as it gives a higher yield. However, the choice of acid derivatives is important. We tend to use an acid anhydride instead of an acyl chloride to make esters for the following reasons:
Esters are important parts of many perfumes and cosmetics, thanks to their fruity smells.
Similarly, acylation of ammonia or primary amines produces amides. These are useful stepping stools in the preparation of many pharmecuticals.
Find out more about esters and amides in their respective articles, Esters and Amides.
Another example of an important acylation reaction is the production of aspirin. Aspirin is manufactured by reacting a compound known commonly as 2-hydroxybenzoic acid, 2-hydroxybenzenecarboxylic acid or simply just salicylic acid, with ethanoic anhydride. The -hydroxy- in the name 2-hydroxybenzoic acid indicates that this molecule contains a hydroxyl group (-OH). 2-hydroxybenzoic acid is therefore a primary alcohol. Its acylation reaction with ethanoic anhydride produces aspirin - an ester - and ethanoic acid.
Aspirin is scientifically known as 2-acetyloxybenzoic acid, but it is also called acetylsalicylic acid, or ASA. The salicylic part of its name gives you a clue to its origins - willow trees. Willows are trees in the family Salicaceae. Chewing willow bark has been a known source of pain relief for centuries. In fact, medicines made from willow and other salicylate-rich plants are even recorded in the Ebers Papyrus from ancient Egypt!
You might synthesise and purify aspirin in class. This involves various different stages of heating, cooling, and filtering, all with the aim of getting a pure product. You can then calculate your percentage yield. It is hard to get a 100 percent yield on such a small scale in a laboratory - can you think of possible reasons why?
Acylation is a type of reaction that involves adding the acyl group, -RCO-, to another molecule.
The acyl group is an organic group with the formula -RCO-. It consists of a carbon atom bonded to an oxygen atom with a double bond, and an R group with a single bond.
You can make acyl chlorides by reacting carboxylic acids with either solid phosphorus(V) chloride or liquid phosphorus(III) chloride.
What happens in an acylation reaction?
The acyl group is added on to another molecule.
What is an acid derivative?
A molecule derived from a carboxylic acid.
Give the general formula of an acid derivative.
RCOZ
Name two types of acid derivative.
Define nucleophile.
An electron pair donor with a lone pair of electrons, and either a negative or partial-negative charge.
Acyl chlorides are more reactive than acid anhydrides. True or false?
True
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