THE ACIDITY OF ORGANIC ACIDS
This page explains the acidity of simple organic acids and looks at the factors which affect their relative strengths. Why are organic acids acidic? Organic acids as weak acids For the purposes of this topic, we are going to take the definition of an acid as "a substance which donates hydrogen ions (protons) to other things". We are going to get a measure of this by looking at how easily the acids release hydrogen ions to water molecules when they are in solution in water. An acid in solution sets up this equilibrium: | |||||||||||||||||||||||||||||||
Note: We are writing the acid as AH rather than HA, because, in all the cases we shall be looking at, the hydrogen we are interested in is at the right-hand end of a molecule. | |||||||||||||||||||||||||||||||
A hydroxonium ion is formed together with the anion (negative ion) from the acid. This equilibrium is sometimes simplified by leaving out the water to emphasise the ionisation of the acid. The organic acids are weak in the sense that this ionisation is very incomplete. At any one time, most of the acid will be present in the solution as un-ionised molecules. For example, in the case of dilute ethanoic acid, the solution contains about 99% of ethanoic acid molecules - at any instant, only about 1% have actually ionised. The position of equilibrium therefore lies well to the left. Comparing the strengths of weak acids The strengths of weak acids are measured on the pKa scale. The smaller the number on this scale, the stronger the acid is. Three of the compounds we shall be looking at, together with their pKa values are: Why are these acids acidic? In each case, the same bond gets broken - the bond between the hydrogen and oxygen in an -OH group. Writing the rest of the molecule as "X": | |||||||||||||||||||||||||||||||
Note: If you aren't sure about coordinate covalent (dative covalent) bonding, you might like to follow this link. It isn't, however, particularly important to the rest of the current page. Use the BACK button on your browser to return to this page later. | |||||||||||||||||||||||||||||||
So . . . if the same bond is being broken in each case, why do these three compounds have such widely different acid strengths? Differences in acid strengths between carboxylic acids, phenols and alcohols The factors to consider Two of the factors which influence the ionisation of an acid are:
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Note: You've got to be a bit careful about this. The bonds won't be identically strong, because what's around them in the molecule isn't the same in each case. | |||||||||||||||||||||||||||||||
The most important factor in determining the relative acid strengths
of these molecules is the nature of the ions formed. You always get a
hydroxonium ion - so that's constant - but the nature of the anion (the
negative ion) varies markedly from case to case.
Ethanoic acid Ethanoic acid has the structure: You might reasonably suppose that the structure of the ethanoate ion was as below, but measurements of bond lengths show that the two carbon-oxygen bonds are identical and somewhere in length between a single and a double bond. | |||||||||||||||||||||||||||||||
Warning! If you don't already understand about the bonding in the carbon-oxygen double bond, you would be well advised to skip this next bit - all the way down to the simplified structure of the ethanoate ion towards the end of it. It goes beyond anything that you are likely to want for UK A level purposes. If you do choose to follow this link, it will probably take you to several other pages before you are ready to come back here again. Use the BACK button (or HISTORY file or GO menu) on your browser to return to this page. | |||||||||||||||||||||||||||||||
Like any other double bond, a carbon-oxygen double bond is made up of
two different parts. One electron pair is found on the line between
the two nuclei - this is known as a sigma bond. The other electron pair
is found above and below the plane of the molecule in a pi bond. Pi bonds are made by sideways overlap between p orbitals on the carbon and the oxygen. In an ethanoate ion, one of the lone pairs on the negative oxygen ends up almost parallel to these p orbitals, and overlaps with them. Because the oxygens are more electronegative than the carbon, the delocalised system is heavily distorted so that the electrons spend much more time in the region of the oxygen atoms. So where is the negative charge in all this? It has been spread around over the whole of the -COO- group, but with the greatest chance of finding it in the region of the two oxygen atoms. Ethanoate ions can be drawn simply as: The more you can spread charge around, the more stable an ion becomes. In this case, if you delocalise the negative charge over several atoms, it is going to be much less attractive to hydrogen ions - and so you are less likely to re-form the ethanoic acid. Phenol Phenols have an -OH group attached directly to a benzene ring. Phenol itself is the simplest of these with nothing else attached to the ring apart from the -OH group. | |||||||||||||||||||||||||||||||
Warning! You need to understand about the bonding in benzene in order to make sense of this next bit. If your syllabus says that you need to know about the acidity of phenol, then you will have to understand the next few paragraphs - which in turn means that you will have to understand about benzene. If it doesn't mention phenol, skip it! If you follow this link, you may have to explore several other pages before you are ready to come back here again. Use the BACK button (or HISTORY file or GO menu) on your browser to return to this page. | |||||||||||||||||||||||||||||||
Delocalisation also occurs in this ion. This time, one of the lone
pairs on the oxygen atom overlaps with the delocalised electrons on the
benzene ring. Think about the ethanoate ion again. If there wasn't any delocalisation, the charge would all be on one of the oxygen atoms, like this: That means that the ethanoate ion won't take up a hydrogen ion as easily as it would if there wasn't any delocalisation. Because some of it stays ionised, the formation of the hydrogen ions means that it is acidic. In the phenoxide ion, the single oxygen atom is still the most electronegative thing present, and the delocalised system will be heavily distorted towards it. That still leaves the oxygen atom with most of its negative charge. What delocalisation there is makes the phenoxide ion more stable than it would otherwise be, and so phenol is acidic to an extent. However, the delocalisation hasn't shared the charge around very effectively. There is still lots of negative charge around the oxygen to which hydrogen ions will be attracted - and so the phenol will readily re-form. Phenol is therefore only very weakly acidic. Ethanol Ethanol, CH3CH2OH, is so weakly acidic that you would hardly count it as acidic at all. If the hydrogen-oxygen bond breaks to release a hydrogen ion, an ethoxide ion is formed: Since ethanol is very poor at losing hydrogen ions, it is hardly acidic at all. Variations in acid strengths between different carboxylic acids You might think that all carboxylic acids would have the same strength because each depends on the delocalisation of the negative charge around the -COO- group to make the anion more stable, and so more reluctant to re-combine with a hydrogen ion. In fact, the carboxylic acids have widely different acidities. One obvious difference is between methanoic acid, HCOOH, and the other simple carboxylic acids:
Why is ethanoic acid weaker than methanoic acid? It again depends on the stability of the anions formed - on how much it is possible to delocalise the negative charge. The less the charge is delocalised, the less stable the ion, and the weaker the acid. The methanoate ion (from methanoic acid) is: But that's important! Alkyl groups have a tendency to "push" electrons away from themselves. That means that there will be a small amount of extra negative charge built up on the -COO- group. Any build-up of charge will make the ion less stable, and more attractive to hydrogen ions. Ethanoic acid is therefore weaker than methanoic acid, because it will re-form more easily from its ions. | |||||||||||||||||||||||||||||||
Note: If you want more information about the inductive effect of alkyl groups, you could read about carbocations (carbonium ions) in the mechanism section of this site. Use the BACK button on your browser to return to this page if you choose to follow this link. | |||||||||||||||||||||||||||||||
The acids can be strengthened by pulling charge away from the -COO- end. You can do this by attaching electronegative atoms like chlorine to the chain.
Attaching different halogens also makes a difference. Fluorine is the most electronegative and so you would expect it to be most successful at pulling charge away from the -COO- end and so strengthening the acid.
Finally, notice that the effect falls off quite quickly as the attached halogen gets further away from the -COO- end. Here is what happens if you move a chlorine atom along the chain in butanoic acid.
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Wednesday, 12 June 2013
THE ACIDITY OF ORGANIC ACIDS
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