Вадим Дудченко
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Magnesium-18 (18Mg) is the lightest isotope of magnesium, which is element 12 on the periodic table.

Magnesium-18. Image credit: S.M. Wang / Fudan University & Facility for Rare Isotope Beams, Michigan State University.

Earth is full of natural magnesium, forged long ago in the stars, that has since become a key component of our diets and minerals in the planet’s crust.

But this magnesium is stable. Its atomic core, or nucleus, doesn’t fall apart.

The magnesium-18 isotope, however, is far too unstable to be found in nature.

All magnesium atoms have 12 protons inside their nuclei. Previously, the lightest version of magnesium had 7 neutrons, giving it a total of 19 protons and neutrons — hence its designation as magnesium-19.

To make magnesium-18, which is lighter by one neutron, Dr. Kyle Brown from the National Superconducting Cyclotron Laboratory at Michigan State University and colleagues started with a stable isotope of magnesium, magnesium-24.

The cyclotron at the National Superconducting Cyclotron Laboratory accelerated a beam of magnesium-24 nuclei to about half the speed of light and sent that beam barreling into a target, which is a metal foil made from the element beryllium. And that was just the first step.

“That collision gives you a bunch of different isotopes lighter than magnesium-24,” Dr. Brown said.

“But from that soup, we can select out the isotope we want.”

In this case, that isotope is magnesium-20. This version is unstable, meaning it decays, usually within tenths of a second.

So the team is on a clock to get that magnesium-20 to collide with another beryllium target about 30 m (100 feet) away.

“But it’s traveling at half the speed of light. It gets there pretty quickly,” Dr. Brown said.

It’s that next collision that creates magnesium-18, which has a lifetime somewhere in the ballpark of a sextillionth of a second.

That’s such a short time that magnesium-18 doesn’t cloak itself with electrons to become a full-fledged atom before falling apart. It exists only as a naked nucleus.

In fact, it’s such a short time that magnesium-18 never leaves the beryllium target. The new isotope decays inside the target.

This means scientists can’t examine the isotope directly, but they can characterize tell-tale signs of its decay.

It first ejects two protons from its nucleus to become neon-16, which then ejects two more protons to become oxygen-14.

By analyzing the protons and oxygen that do escape the target, the team can deduce properties of magnesium-18.

“This was a team effort. Everyone worked really hard on this project. It’s pretty exciting. It’s not every day people discover a new isotope,” Dr. Brown said.

The results were published in the journal Physical Review Letters.


Y. Jin et al. 2021. First Observation of the Four-Proton Unbound Nucleus 18Mg. Phys. Rev. Lett 127 (26): 262502; doi: 10.1103/PhysRevLett.127.262502


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