Making nitriles from
aldehydes and ketones
Aldehydes and ketones
undergo an addition reaction with hydrogen cyanide. The hydrogen
cyanide adds
across the carbon-oxygen double bond in the aldehyde or ketone to produce
a
hydroxynitrile. Hydroxynitriles used to be known as cyanohydrins.
For example, with
ethanal (an aldehyde) you get 2-hydroxypropanenitrile:
With propanone (a
ketone) you get 2-hydroxy-2-methylpropanenitrile:
In every example of
this kind, the -OH group will be on the number 2 carbon atom -
the one next
to the -CN group.
The reaction isn't
normally done using hydrogen cyanide itself, because this is an extremely
poisonous
gas. Instead, the aldehyde or ketone is mixed with a solution of sodium or
potassium cyanide in water to which a little sulphuric acid has been added.
The pH of
the solution is adjusted to about 4 - 5, because this gives the
fastest reaction. The
reaction happens at room temperature.
The solution will
contain hydrogen cyanide (from the reaction between the sodium or
potassium
cyanide and the sulphuric acid), but still contains some free cyanide ions.
This is important for the mechanism.
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These are useful
reactions because they not only increase the number of carbon atoms in
a
chain, but also introduce another reactive group as well as the -CN group.
The -OH group
behaves just like the -OH group in any alcohol with a similar
structure.
For example, starting
from a hydroxynitrile made from an aldehyde, you can quite easily
produce
relatively complicated molecules like 2-amino acids - the amino acids which
are
used to construct proteins.
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infobank for readers and discoverers
Sunday, 30 April 2017
Making nitriles from aldehydes and ketones
reducing nitriles to primary amines
REDUCING NITRILES TO PRIMARY AMINES
This page looks at the reduction of nitriles to primary
amines using either lithium tetrahydridoaluminate(III) (lithium aluminium
hydride) or hydrogen and a metal catalyst.
The reduction of nitriles using LiAlH4
The reducing agent
Despite its name, the structure of the reducing agent is
very simple. There are four hydrogens ("tetrahydido") around the
aluminium in a negative ion (shown by the "ate" ending).
The "(III)" shows the oxidation state of the
aluminium, and is often left out because aluminium only ever shows the +3
oxidation state in its compounds. To make the name shorter, that's what I
shall do for the rest of this page.
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The structure of LiAlH4
is:
In the negative ion,
one of the bonds is a co-ordinate covalent (dative covalent) bond using the
lone pair on a hydride ion (H-) to form a bond with an empty
orbital on the aluminium.
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The overall reaction
The nitrile reacts
with the lithium tetrahydridoaluminate in solution in ethoxyethane (diethyl
ether, or just "ether") followed by treatment of the product of
that reaction with a dilute acid.
Overall, the
carbon-nitrogen triple bond is reduced to give a primary amine. Primary
amines contain the -NH2 group.
For example, with
ethanenitrile you get ethylamine:
Notice that this is a
simplified equation - perfectly acceptable to UK A level examiners. [H] means
"hydrogen from a reducing agent".
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The reduction of nitriles using hydrogen and a metal catalyst
The reduction of
nitriles using hydrogen and a metal catalyst
The carbon-nitrogen
triple bond in a nitrile can also be reduced by reaction with hydrogen
gas in the presence of a variety of metal catalysts.
Commonly quoted
catalysts are palladium, platinum or nickel.
The reaction will take
place at a raised temperature and pressure. It is impossible to give
exact details because it will vary from catalyst to catalyst.
For example,
ethanenitrile can be reduced to ethylamine by reaction with hydrogen in the
presence of a palladium catalyst. |
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The different kinds of amines
What are amines?
The easiest way to
think of amines is as near relatives of ammonia, NH3.
In amines, the
hydrogen atoms in the ammonia have been replaced one at a time by hydrocarbon
groups. On this page, we are only looking at cases where the hydrocarbon
groups are simple alkyl groups.
The different kinds of
amines
Amines fall into
different classes depending on how many of the hydrogen atoms are replaced.
Primary amines
In primary amines,
only one of the hydrogen atoms in the ammonia molecule has been replaced.
That means that the formula of the primary amine will be RNH2
where "R" is an alkyl group.
Examples include:
Naming amines can be
quite confusing because there are so many variations on the names. For
example, the simplest amine, CH3NH2, can be called
methylamine, methanamine or aminomethane.
The commonest name at
this level is methylamine and, similarly, the second compound drawn above is
usually called ethylamine.
Where there might be
confusion about where the -NH2 group is attached to a chain, the
simplest way of naming the compound is to use the "amino" form.
For example:
Secondary amines
In a secondary amine,
two of the hydrogens in an ammonia molecule have been replaced by hydrocarbon
groups. At this level, you are only likely to come across simple ones where
both of the hydrocarbon groups are alkyl groups and both are the same.
For example:
There are other
variants on the names, but this is the commonest and simplest way of naming
these small secondary amines.
Tertiary amines
In a tertiary amine,
all of the hydrogens in an ammonia molecule have been replaced by hydrocarbon
groups. Again, you are only likely to come across simple ones where all three
of the hydrocarbon groups are alkyl groups and all three are the same.
The naming is similar
to secondary amines. For example:
Physical properties of
amines
Boiling points
The table shows the
boiling points of some simple amines.
We will need to look
at this with some care to sort out the patterns and reasons. Concentrate
first on the primary amines.
Primary amines
It is useful to
compare the boiling point of methylamine, CH3NH2, with
that of ethane, CH3CH3.
Both molecules contain
the same number of electrons and have, as near as makes no difference, the
same shape. However, the boiling point of methylamine is -6.3°C, whereas
ethane's boiling point is much lower at -88.6°C.
The reason for the
higher boiling points of the primary amines is that they can form hydrogen
bonds with each other as well as van der Waals dispersion forces and
dipole-dipole interactions.
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