Image caption The Dzero team is also part of a mystery about a potential new particle

US particle physicists are inching closer to determining why the Universe exists in its current form, made overwhelmingly of matter.

Physics suggests equal amounts of matter and antimatter should have been made in the Big Bang.

In 2010, researchers at the Tevatron accelerator claimed preliminary results showing a small excess of matter over antimatter as particles decayed.

The team has submitted a paper showing those results are on a firmer footing.

Each of the fundamental particles known has an antimatter cousin, with identical properties but opposite electric charge.

When a particle encounters its antiparticle, they "annihilate" each other, disappearing in a high-energy flash of light.

The question remains: why did this not occur in the early Universe with the equal amounts of matter and antimatter, resulting in a Universe devoid of both?

New physics?

The Tevatron results come from a shower of particles produced at the facility when smashing protons into their antimatter counterparts, antiprotons.

The proton-antiproton collisions in turn create a number of different particles, and the team operating the Tevatron's DZero detector first noticed a discrepancy in the decay of particles called B mesons.

Statistics of a 'discovery' Particle physics has an accepted definition for a "discovery": a five-sigma level of certainty

The number of standard deviations, or sigmas, is a measure of how unlikely it is that an experimental result is simply down to chance, in the absence of a real effect

Similarly, tossing a coin and getting a number of heads in a row may just be chance, rather than a sign of a "loaded" coin

The "three sigma" level represents about the same likelihood as tossing nine heads in a row

Five sigma, on the other hand, would correspond to tossing more than 21 in a row

Unlikely results are more probable when several experiments are carried out at once - equivalent to several people flipping coins at the same time

With independent confirmation by other experiments, five-sigma findings become accepted discoveries

These decayed into pairs of particles called muons alongside pairs of their antimatter versions, antimuons. But, as the team reported in May 2010 in a paper published in Physical Review Letters, there was a notable 1% excess of the matter particles.

However, unpicking important events in the soup of interactions created in particle physics experiments meant that those measurements were associated with a level of uncertainty - reflecting the probability that the effect they see is a random statistical occurrence, rather than new physics.

The researchers now have 50% more data to work with, and have tried to establish that their earlier result in fact came from the particle decays that they first proposed.

As they reported this Thursday, they have now reduced the uncertainty in their experiment to a level of "3.9 sigma", or 3.9 standard deviations - equivalent to a 0.005% probability that the effect is a fluke.

But particle physics has a strict definition for what may be called a discovery - the "five sigma" level of certainty, or about a 0.00003% chance that the effect is not real - which the team must show before they can claim to have solved the long-standing matter/antimatter mystery.