Everything on earth is made up of combinations of different elements –
all of which can be found on the periodic table. Considering that the
periodic table contains 118 elements it seems a pity that organic life
tends to feature only five or six of those elements in any vast
quantities. The main one being carbon.
It would be impossible for life on earth to exist without carbon. Carbon
is the main component of sugars, proteins, fats, DNA, muscle tissue,
pretty much everything in your body. The reason carbon is so special is
down to the electron configuration of the individual atoms. Electrons
exist in concentric ‘shells’ around the central nucleus and carbon has
four electrons in its outermost shell. As the most stable thing for an
atom to have is eight electrons, this means that each carbon can form
four bonds with surrounding atoms.
Each bond in the above molecule is formed by the sharing of two
electrons; one from the carbon and one from the hydrogen. The ability to
form four bonds isn’t restricted to carbon though, it’s a property of
every atom with four outer electrons, including silicon, tin and lead.
What’s special about carbon, and the reason that silicon-based lifeforms
are restricted to science fiction (and lead-based lifeforms are hardly
ever mentioned) is that it can form double-bonds which share more than
one electron with another atom, as shown below:
Why is carbon able to do this while silicon can’t? Although the bonds
are all drawn as straight lines in the diagram above, in real life not
all bonds are equal. The double bond consists of two different types of
bond. Each bond is made up of two electron orbitals (one from each atom)
which have overlapped. The easiest way to think of an orbital without
getting into some serious physics is as a blurry sort of zone in which a
fast-moving electron is most likely to be whizzing about. When two
orbitals overlap, you have double the space which two electrons can whiz
around in.
The single bond is formed by two circular orbitals overlapping and surrounding both atoms:
The second bond is formed slightly differently. The electrons that form
these bonds are not in a spherical orbital around the nucleus, they are
in oval-shaped orbitals that protrude above and below the nucleus. When
they overlap the bond forms above and below the first bond, as shown in
the diagram:
So why can carbon and not silicon manage this double-bond trick? The
answer lies in the size. Carbon is the smallest of all the atoms with
four outermost electrons, which means that the electrons in the
above-and-below orbitals are close enough to overlap and form that
second bond. For silicon however, there are more electron orbitals in
the way, the entire atom is bigger, and it is almost impossible for the
outer orbitals to get close enough to form a double bond. This is why
carbon dioxide is is a small gaseous molecule consisting of two oxygens
both forming a double bond with a single carbon while silicon dioxide is
a massive behemoth of a molecule made of huge numbers of
alternating oxygen and silicon atoms and is more commonly known as sand.
You can just about get silicon-silicon double bonds if you try hard, but
they are fairly unstable and will take any chance they can to loose
that double-bond in favour of forming another single one. Carbon-carbon
double bonds on the other hand form naturally and easily, and are
crucial for every living organism on earth. If there were to be
silicon-based lifeforms, the sheer chemistry of their atoms means that
they would have to be built along very different lines to life on earth.
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