An analogue was found in a liquid helium concoction
It could provide clues about how cosmic defects form
Can you model what happened in the early universe in the laboratory? Yes, according to one group of physicists. A team at Lancaster University in the United Kingdom has used liquid helium and a magnetic field to build a finger-sized representation of the early cosmos. Period of expansion
Their findings could help string theorists to refine their models. It is thought that shortly after the Big Bang, the nascent universe underwent a very rapid period of expansion, known as inflation.
But theorists are still debating what drove the rapid growth. A popular theory among string theorists is that inflation was caused by the collision of two ‘branes.’
A brane (derived from the word ‘membrane’) is a three-dimensional object suspended in a higher-dimensional space, in the same way that a sheet of paper is a two-dimensional object in a three-dimensional space.
One idea within string theory is that our entire universe sits on a single such brane, and that it was our brane’s collision with another that drove inflation.
The question is how to test this theory: finding two universe-sized objects that you can crash into each other might be slightly difficult.
Liquid heliumBut a good analogue can be found in a strange concoction of liquid helium, according to Richard Haley, who led the team at Lancaster University. Haley and his group used an 8mm by 45mm cylinder filled with helium-3, an isotope of helium that contains two protons and a single neutron.
When cooled to just 150 microkelvin above absolute zero, helium-3 becomes a superfluid and begins to take on some odd traits: Ghostly ‘quasi-particles’ are formed that can flit effortlessly through the frigid liquid.
And the entire system can undergo ‘symmetry breaking’ — a phenomenon also thought to have led to the creation of every force we see today except gravity.
It also tends to settle into one of two phases, which physicists label A and B. The team used a magnetic field to create an A-phase slice of helium-3 sandwiched between two sections of B-phase liquid.
Radically differentThey then decreased the field and watched as the two B-phases collided. The colliding phases were, believe it or not, good analogues for colliding branes, Haley says. While helium-3 is radically different from the vacuum of space, the mathematics governing the two systems are similar.
Haley and his team found evidence of defects — similar to those predicted by brane theory — left over from the collision.
Normally, quasi-particles can move with no resistance through superfluid helium-3, but have trouble crossing between A and B phases.
Haley’s team found the quasi-particles still encountered resistance even after the A-phase was completely removed.
The most likely explanation is that their flow was impeded by strange, quantum-mechanical vortices left over from the collision, the team says.
Cosmic stringsUniverse-sized brane collisions are thought to leave behind a tangle of defects called ‘cosmic strings’ — massive, spaghetti-like objects that would crisscross the entire cosmos.
None have been seen to date, but theorists believe that their gravity waves might one day be detected by specialised instruments. This lab model of brane theory is far from perfect, says Cliff Burgess, a theorist at the Perimeter Institute for Theoretical Physics in Waterloo, Canada.
Speed of lightFor example, branes on the universal scale move at close to the speed of light and crinkle more easily than helium-3 branes.
But nevertheless, he says, the liquid helium-3 analogue could provide some clues about how cosmic defects form and what they might look like.
Haley says his team will now begin trying to characterise the exact nature of the defects created when their little branes collide.
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