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Medieval alchemists dreamed of transmuting lead into gold.

Today, we know that lead and gold are different elements, and no amount of chemistry can turn one into the other.

But our modern knowledge tells us the basic difference between an atom of lead and an atom of gold: the lead atom contains exactly three more protons. So can we create a gold atom by simply pulling three protons out of a lead atom?

As it turns out, we can. But it’s not easy.

Lead and gold are different elements, with three protons’ difference between them

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Lead and gold are different elements, with three protons’ difference between them (University of Seville)

While smashing lead atoms into each other at extremely high speeds in an effort to mimic the state of the universe just after the Big Bang, physicists working on the ALICE experiment at the Large Hadron Collider in Switzerland incidentally produced small amounts of gold.

Extremely small amounts, in fact: a total of some 29 trillionths of a gram.

How to steal a proton

Protons are found in the nucleus of an atom. How can they be pulled out?

Well, protons have an electric charge, which means an electric field can pull or push them around. Placing an atomic nucleus in an electric field could do it.

However, nuclei are held together by a very strong force with a very short range, imaginatively known as the strong nuclear force. This means an extremely powerful electric field is required to pull out protons – about a million times stronger than the electric fields that create lightning bolts in the atmosphere.

The way the scientists created this field was to fire beams of lead nuclei at each other at incredibly high speeds – almost the speed of light.

Scientists working on the Large Hadron Collider created tiny amounts of gold by accident

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Scientists working on the Large Hadron Collider created tiny amounts of gold by accident (PA)

The magic of a near-miss

When the lead nuclei have a head-on collision, the strong nuclear force comes into play and they end up getting completely destroyed. But more commonly the nuclei have a near miss, and only affect each other via the electromagnetic force.

The strength of an electric field drops off very quickly as you move away from an object with an electric charge (such as a proton). But at very short distances, even a tiny charge can create a very strong field.

So when one lead nucleus just grazes past another, the electric field between them is huge. The rapidly changing field between the nuclei makes them vibrate and occasionally spit out some protons. If one of them spits out exactly three protons, the lead nucleus has turned into gold.

A man rides his bicycle along the underground Large Hadron Collider during its hiatus in 2020

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A man rides his bicycle along the underground Large Hadron Collider during its hiatus in 2020 (AFP via Getty)

Counting protons

So if you have turned a lead atom into gold, how do you know? In the ALICE experiment, they use special detectors called zero-degree calorimeters to count the protons stripped out of the lead nuclei.

They can’t observe the gold nuclei themselves, so they only know about them indirectly.

About the author

Ulrik Egede is a Professor of Physics at Monash University.

This article was originally published by The Conversation and is republished under a Creative Commons licence. Read the original article.

The ALICE scientists calculate that, while they are colliding beams of lead nuclei, they produce about 89,000 gold nuclei per second. They also observed the production of other elements: thallium, which is what you get when you take one proton from lead, as well as mercury (two protons).

An alchemical nuisance

Once a lead nucleus has transformed by losing protons, it is no longer on the perfect orbit that keeps it circulating inside the vacuum beam pipe of the Large Hadron Collider. In a matter of microseconds it will collide with the walls.

This effect makes the beam less intense over time. So for scientists, the production of gold at the collider is in fact more of a nuisance than a blessing.

However, understanding this accidental alchemy is essential for making sense of experiments – and for designing the even bigger experiments of the future.