Higgs boson results from LHC 'get even stronger'

2012-08-01 06:38:31

The Higgs boson-like particle whose discovery was announced on 4 July looks

significantly more certain to exist.

The particle has been the subject of a decades-long hunt as the last missing

piece of physics' Standard Model, explaining why matter has mass.

Now Higgs-hunting teams at the Large Hadron Collider report more than "5.8

sigma" levels of certainty it exists.

That equates to a one-in-300 million chance that the Higgs does not exist and

the results are statistical flukes.

Statistics of a 'discovery'

Two-pence piece

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 rather than 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 of tossing more

than eight heads in a row

Five sigma, on the other hand, would correspond to tossing more than 20 in a

row

Unlikely results can occur if several experiments are being 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

The formal threshold for claiming the discovery of a particle is a 5-sigma

level - equivalent to a one-in-3.5 million chance.

That is the level that was claimed by the team behind Atlas, one of the LHC's

Higgs-hunting experiments, during the 4 July announcement. The other, known as

CMS, claimed results between 4.9 and 5 sigma.

The range reported by CMS at the time reflects the fact that there are a number

of ways to look for the Higgs boson, none of which can observe it directly.

Accelerators like the LHC smash together particles at extraordinary energies in

a bid to create a Higgs, which should exist only for a fleeting fraction of a

second before decaying into other particles or flashes of light that can be

caught and counted.

Now both Atlas and CMS have submitted fuller analyses of these "decay

channels", incorporating more data at the heightened particle energies at which

the LHC is running this year.

The CMS team reports online in a paper submitted to Physics Letters B that

their results now reach a significance of 5.8 sigma.

The Atlas team, in a paper submitted to the same journal, report their results

from data corresponding to a channel in which the Higgs ends up as two lighter

particles known as W bosons.

They reach a significance of 5.9 sigma - jumping to a one-in-550 million chance

that, in the absence of a Higgs, the signals they see would be recorded.

The findings only shore up a result that, as far as physicists were concerned,

had already passed muster for declaring the existence of a new particle.

However, many questions remain as to whether the particle is indeed the

long-sought Higgs boson; the announcement was carefully phrased to describe a

"Higgs-like" particle.

More analyses will be needed to ensure it fits neatly into the Standard Model -

the most complete theory we have for particles and forces - as it currently

exists.

The Standard Model and the Higgs boson

Standard model

The Standard Model is the simplest set of ingredients - elementary particles

- needed to make up the world we see in the heavens and in the laboratory

Quarks combine together to make, for example, the proton and neutron - which

make up the nuclei of atoms today - though more exotic combinations were around

in the Universe's early days

Leptons come in charged and uncharged versions; electrons - the most familiar

charged lepton - together with quarks make up all the matter we can see; the

uncharged leptons are neutrinos, which rarely interact with matter

The "force carriers" are particles whose movements are observed as familiar

forces such as those behind electricity and light (electromagnetism) and

radioactive decay (the weak nuclear force)

The Higgs boson came about because although the Standard Model holds together

neatly, nothing requires the particles to have mass; for a fuller theory, the

Higgs - or something else - must fill in that gap