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Justin Rowlatt By Justin Rowlatt Presenter, Business Daily, BBC World Service
Mankind's attitude to gold is bizarre. Chemically, it is uninteresting - it
barely reacts with any other element. Yet, of all the 118 elements in the
periodic table, gold is the one we humans have always tended to choose to use
as currency. Why?
Why not osmium or chromium, or helium, say - or maybe seaborgium?
I'm not the first to ask the question, but I like to think I'm asking it in one
of the most compelling locations possible - the extraordinary exhibition of
pre-Columbian gold artefacts at the British Museum?
That's where I meet Andrea Sella, a professor of chemistry at University
College London, beside an exquisite breastplate of pure beaten gold.
He pulls out a copy of the periodic table.
Periodic table
"Some elements are pretty easy to dismiss," he tells me, gesturing to the
right-hand side of the table.
"Here you've got the noble gases and the halogens. A gas is never going to be
much good as a currency. It isn't really going to be practical to carry around
little phials of gas is it?
Gold - key facts
Gold - symbol, atomic number and weight
Symbol: Au (from Latin aurum)
Atomic number: 79
Weight: 196.97
One of the "noble" metals that do not oxidise under ordinary conditions
Used in jewellery, electronics, aerospace and medicine
Most gold in the earth's crust is thought to derive from meteors
Biggest producers: China, Australia, US, Russia
US Geological Survey: Gold
"And then there's the fact that they are colourless. How on earth would you
know what it is?"
The two liquid elements (at everyday temperature and pressure) - mercury and
bromine - would be impractical too. Both are also poisonous - not a good
quality in something you plan to use as money. Similarly, we can cross out
arsenic and several others.
Sella now turns his attention to the left-hand side of the table.
"We can rule out most of the elements here as well," he says confidently.
"The alkaline metals and earths are just too reactive. Many people will
remember from school dropping sodium or potassium into a dish of water. It
fizzes around and goes pop - an explosive currency just isn't a good idea."
A similar argument applies to another whole class of elements, the radioactive
ones: you don't want your cash to give you cancer.
Out go thorium, uranium and plutonium, along with a whole bestiary of
synthetically-created elements - rutherfordium, seaborgium, ununpentium,
einsteinium - which only ever exist momentarily as part of a lab experiment,
before radioactively decomposing.
Then there's the group called "rare earths", most of which are actually less
rare than gold.
Unfortunately, they are chemically hard to distinguish from each other, so you
would never know what you had in your pocket.
This leaves us with the middle area of the periodic table, the "transition" and
"post-transition" metals.
This group of 49 elements includes some familiar names - iron, aluminium,
copper, lead, silver.
But examine them in detail and you realise almost all have serious drawbacks.
We've got some very tough and durable elements on the left-hand side - titanium
and zirconium, for example.
The problem is they are very hard to smelt. You need to get your furnace up
into the region of 1,000C before you can begin to extract these metals from
their ores. That kind of specialist equipment wasn't available to ancient man.
Aluminium is also hard to extract, and it's just too flimsy. Most of the others
in the group aren't stable - they corrode if exposed to water or oxidise in the
air.
Take iron. In theory it looks quite a good prospect for currency. It is
attractive and polishes up to a lovely sheen. The problem is rust: unless you
keep it completely dry it is liable to corrode away.
"A self-debasing currency is clearly not a good idea," says Sella.
We can rule out lead and copper on the same basis. Both are liable to
corrosion. Societies have made both into money but the currencies did not last,
literally.
So, what's left?
Why is gold golden?
2,000-year-old golden funerary mask from Colombia
Gold's golden colour has been a mystery until very recently, says Andrea Sella.
The secret lies in its atomic structure. "Quantum mechanics alone doesn't
explain it," he says.
"When you get to gold you find the atom is so heavy and the electrons move so
fast that you now have to include Einstein's theory of relativity into the
mathematics.
"It is only when you fold together quantum mechanics with relativity that
suddenly you understand it."
Unlike other metals, which in their pure form reflect light straight back, gold
molecules "slosh around a little," Sella says, with the result that gold
"absorbs a bit of the blue spectrum light, giving the light that is reflected
back its distinctive golden colour".
Of the 118 elements we are now down to just eight contenders: platinum,
palladium, rhodium, iridium, osmium and ruthenium, along with the old
familiars, gold and silver.
These are known as the noble metals, "noble" because they stand apart, barely
reacting with the other elements.
They are also all pretty rare, another important criterion for a currency.
Even if iron didn't rust, it wouldn't make a good basis for money because
there's just too much of it around. You would end up having to carry some very
big coins about.
With all the noble metals except silver and gold, you have the opposite
problem. They are so rare that you would have to cast some very tiny coins,
which might easily lose.
They are also very hard to extract. The melting point of platinum is 1,768C.
That leaves just two elements - silver and gold.
Both are scarce but not impossibly rare. Both also have a relatively low
melting point, and are therefore easy to turn into coins, ingots or jewellery.
Silver tarnishes - it reacts with minute amounts of sulphur in the air. That's
why we place particular value on gold.
It turns out then, that the reason gold is precious is precisely that it is so
chemically uninteresting.
Gold's relative inertness means you can create an elaborate golden jaguar and
be confident that 1,000 years later it can be found in a museum display case in
central London, still in pristine condition.
So what does this process of elemental elimination tell us about what makes a
good currency?
First off, it doesn't have to have any intrinsic value. A currency only has
value because we, as a society, decide that it does.
Start Quote
That's the other secret of gold's success as a currency - gold is unbelievably
beautiful
Andrea Sella
As we've seen, it also needs to be stable, portable and non-toxic. And it needs
to be fairly rare - you might be surprised just how little gold there is in the
world.
If you were to collect together every earring, every gold sovereign, the tiny
traces gold in every computer chip, every pre-Columbian statuette, every
wedding ring and melt it down, it's guesstimated that you'd be left with just
one 20-metre cube, or thereabouts.
But scarcity and stability aren't the whole story. Gold has one other quality
that makes it the stand-out contender for currency in the periodic table. Gold
is... golden.
All the other metals in the periodic table are silvery-coloured except for
copper - and as we've already seen, copper corrodes, turning green when exposed
to moist air. That makes gold very distinctive.
"That's the other secret of gold's success as a currency," says Sella. "Gold is
unbelievably beautiful."
But how come no-one actually uses gold as a currency any more?
Chart showing gold price adjusted for inflation
The seminal moment came in 1973, when Richard Nixon decided to sever the US
dollar's tie to gold.
Since then, every major currency has been backed by no more than legal "fiat" -
the law of the land says you must accept it as payment.
Nixon made his decision for the simple reason that the US was running out of
the necessary gold to back all the dollars it had printed.
And here lies the problem with gold. Its supply bear no relation to the needs
of the economy. The supply of gold depends on what can be mined.
In the 16th Century, the discovery of South America and its vast gold deposits
led to an enormous fall in the value of gold - and therefore an enormous
increase in the price of everything else.
Since then, the problem has typically been the opposite - the supply of gold
has been too rigid. For example, many countries escaped the Great Depression in
the 1930s by unhitching their currencies from the Gold Standard. Doing so freed
them up to print more money and reflate their economies.
The demand for gold can vary wildly - and with a fixed supply, that can lead to
equally wild swings in its price.
Most recently for example, the price has gone from $260 per troy ounce in 2001,
to peak at $1,921.15 in September 2011, before falling back to $1,230
currently.
That is hardly the behaviour of a stable store of value.
So, to paraphrase Churchill, out of all the elements, gold makes the worst
possible currency.
Apart from all the others.