The protons and neutrons that make up the nuclei of atoms are made of elementary particles known as quarks. Protons and neutrons are made up of the lightest and most stable flavours of quark: the up quark and down quark.
The heaviest and most unstable flavour of quark is the top quark, which current experiments suggest is about 184 times heavier than the proton.
Now, theoretical physicists have found that if the top quark is heavier than currently thought, the energy suffusing the vacuum of empty space may one day destabilise.
First, microscopic bubbles would appear and affect the Higgs field, which pervades space and is responsible for the masses of particles such as electrons and quarks.
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Those tiny bubbles in space, however, would cause the Higgs field to have lower energy than its current value.
"These bubbles appear only rarely, but when they do, they expand at close to the speed of light," Carroll said.
If such a bubble were to hit Earth, the masses of all the particles that depend on the Higgs field would suddenly change and no living creature would survive.
If the universe is not doomed by the top quark, it could face an even stranger fate - one dominated by so-called Boltzmann Brains - in which any random event, no matter how unlikely, could happen, given enough time.
However, if the top quark is massive enough to potentially doom all life, then the energy of the vacuum would be low enough to avoid the concept of Boltzmann Brains.
In order "to bring on rapid cosmic doomsday and avoid the Boltzmann Brain menace," the top quark's mass needs to be about 178 billion electron volts, corresponding to 188 times the mass of the proton, Carroll said.
This is about 3 per cent heavier than the top quark's current measured mass of 173 billion electron volts, "but there are uncertainties on that measurement, and the top quark could easily be a few billion electron volts heavier than we think," he added.