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This page looks at the reactions of the Group 1 elements -
lithium, sodium, potassium, rubidium and caesium - with water. It uses these
reactions to explore the trend in reactivity in Group 1.
The Facts
General
All of these metals react vigorously or even explosively
with cold water. In each case, a solution of the metal hydroxide is produced
together with hydrogen gas.
 
This equation applies to any of these metals and water -
just replace the X by the symbol you want.
In each of the following descriptions, I am assuming a
very small bit of the metal is dropped into water in a fairly large
container.
Details for the individual metals
Lithium
Lithium's density is only about half that of water so it
floats on the surface, gently fizzing and giving off hydrogen. It gradually
reacts and disappears, forming a colourless solution of lithium hydroxide.
The reaction generates heat too slowly and lithium's melting point is too
high for it to melt (see sodium below).
Sodium
Sodium also floats on the surface, but enough heat is
given off to melt the sodium (sodium has a lower melting point than lithium
and the reaction produces heat faster) and it melts almost at once to form a
small silvery ball that dashes around the surface. A white trail of sodium
hydroxide is seen in the water under the sodium, but this soon dissolves to
give a colourless solution of sodium hydroxide.
The sodium moves because it is pushed around by the
hydrogen which is given off during the reaction. If the sodium becomes
trapped on the side of the container, the hydrogen may catch fire to burn
with an orange flame. The colour is due to contamination of the normally blue
hydrogen flame with sodium compounds.
Potassium
Potassium behaves rather like sodium except that the
reaction is faster and enough heat is given off to set light to the hydrogen.
This time the normal hydrogen flame is contaminated by potassium compounds
and so is coloured lilac (a faintly bluish pink).
Rubidium
Rubidium is denser than water and so sinks. It reacts
violently and immediately, with everything spitting out of the container
again. Rubidium hydroxide solution and hydrogen are formed.
Caesium
Caesium explodes on contact with water, quite possibly
shattering the container. Caesium hydroxide and hydrogen are formed
Summary of the trend in reactivity
The Group 1 metals become more reactive towards water as
you go down the Group.
Explaining the trend in reactivity
Looking at the enthalpy changes for the reactions
The overall enthalpy changes
You might think that because the reactions get more
dramatic as you go down the Group, the amount of heat given off increases as
you go from lithium to caesium. Not so!
The table gives estimates of the enthalpy change for each
of the elements undergoing the reaction:
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Note: That's the same equation as before, but
I have divided it by two to show the enthalpy change per mole of metal
reacting.
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You will see that there is no pattern at all in
these values. They are all fairly similar and, surprisingly, lithium
is the metal which releases the most heat during the reaction!
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Note: Apart from the lithium value, I haven't
been able to confirm these figures. For lithium, sodium and potassium, they
are calculated values based on information in the Nuffield Advanced Science
Book of Data (page 114 of my 1984 edition). The lithium value agrees almost
exactly with a value I found during a web search. The values for rubidium and
caesium are calculated indirectly from the Li, Na and K values and other
information which you will find in a later table on this page.
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Digging around in the enthalpy changes
When these reactions happen, the differences between them
lie entirely in what is happening to the metal atoms present. In each case,
you start with metal atoms in a solid and end up with metal ions in solution.
Overall, what happens to the metal is this:
You can calculate the overall enthalpy change for this
process by using Hess's Law and breaking it up into several steps that we
know the enthalpy changes for.
First, you would need to supply atomisation energy
to give gaseous atoms of the metal.
Then ionise the metal by supplying its first ionisation
energy.
And finally, you would get hydration enthalpy
released when the gaseous ion comes into contact with water.
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Note: There is no suggestion that the
reaction actually happens by this route. All we are doing is inventing an
imaginary route from the start to the end point of the reaction, and using
Hess's Law to say that the overall enthalpy change will be exactly the same
as we can calculate using this imaginary route. If you don't know about
Hess's Law, you probably aren't likely to be making much sense of all this
bit of the page anyway. If you aren't happy about enthalpy changes, you might
want to explore the energetics
section of Chemguide, or my chemistry calculations
book.
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If we put values for all these steps into a table, they
look like this (all values in kJ / mol):
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Note: Remember that these aren't the overall
enthalpy changes for the reactions when the metal reacts with water. They are
only for that part of the reaction which involves the metal. There are also
changes going on with the water present - turning it into hydrogen gas and
hydroxide ions. To get the total enthalpy changes, you would have to add
these values in as well.
The changes due to the water will, however, be the same
for each reaction - in each case about -382 kJ / mol. Adding that on to the
figures in this table gives the values in the previous one to within a kJ or
two. The rubidium and caesium values will agree exactly, because that's how I
had to calculate them in the first table. The other three in the previous
table were calculated from information from a different source.
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So why isn't there any pattern in these values? If you
look at the various bits of information, you will find that as you go down
the Group each of them decreases:
What is happening is that the various factors are falling
at different rates. That destroys any overall pattern.
It is, however, possible to look at the table again and
find a pattern which is useful.
Looking at the activation energies for the reactions
Let's take the last table and just look at the energy
input terms - the two processes where you have to supply energy to make them
work. In other words, we will miss out the hydration enthalpy term and just
add up the other two.
Now you can see that there is a steady fall as you go down
the Group. As you go from lithium to caesium, you need to put less energy
into the reaction to get a positive ion formed. This energy will be recovered
later on (plus quite a lot more!), but has to be supplied initially. This is
going to be related to the activation energy of the reaction.
The lower the activation energy, the faster the reaction.
So although lithium releases most heat during the
reaction, it does it relatively slowly - it isn't all released in one short,
sharp burst. Caesium, on the other hand, has a significantly lower activation
energy, and so although it doesn't release quite as much heat overall, it
does it extremely quickly - and you get an explosion.
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Note: You need to be a bit careful about how
you phrase this! You probably haven't noticed my use of the phrase "This
is going to be related to the activation energy of the reaction."
In rewriting it, I have emphasised the words "related to".
The reaction certainly won't involve exactly the energy terms
we are talking about. The metal won't first convert to gaseous atoms
which then lose an electron. But at some point, atoms will have to break away
from the metal structure and they will have to lose electrons.
However, other energy releasing processes may
happen at exactly the same time - for example, if the metal atom loses an
electron, something almost certainly picks it up simultaneously. The electron
is never likely to be totally free. That will have the effect of reducing the
height of the real activation energy barrier. The values we have calculated
by adding up the atomisation and ionisation energies are very big in
activation energy terms and the reactions would be extremely slow if they
were for real.
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Summarising the reason for the increase in reactivity
as you go down the Group
The reactions become easier as the energy needed to form
positive ions falls. This is in part due to a decrease in ionisation energy
as you go down the Group, and in part to a fall in atomisation energy
reflecting weaker metallic bonds as you go from lithium to caesium. This
leads to lower activation energies, and therefore faster reactions.
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Note: If you are a UK A level student, you
will almost certainly find that your examiners will only expect you to
explain this in terms of the fall in ionisation energy as you go down the
Group. In other words, they simplify things by overlooking the contribution
from atomisation energy. Stick with what your examiners expect - don't make
life difficult for yourself! I'm trying to be as rigorous as I can because a
sizeable part of my audience is working in systems outside the UK or beyond A
level.
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Where would you like to go now?
© Jim Clark 2005
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