by SANDY ANDERSON
Based on the data produced by big detectors like
CMS at CERN, Geneva, the structure of matter can be studied in detail. (Photo:
KIT/Markus Breig)
How many matter particles exist in nature?
Particle physicists have been dealing with this question for a long time. The
12 matter particles contained in the standard model of particle physics? Or are
there further particles with too high a mass to be produced by the experiments
performed so far? These questions are now answered by researchers of KIT, CERN,
and Humboldt University in the current issue of the Physical Review Letters.
(DOI: 10.1103/PhysRevLett.109.241802)
Matter particles, also called fermions, are the
elementary components of the universe. They make up everything we see on earth
or through telescopes. "For a long time, however, it was not clear whether
we know all components," explains Ulrich Nierste, Professor at KIT. The
standard model of particle physics knows 12 fermions. Based on their similar
properties, they are divided into three generations of four particles each.
Only the first generation of particles occurs in appreciable amount outside of
particle accelerators. Among these particles are the electron, the electron
neutrino, and the up-quark and down-quark. Up- and down-quarks form heavier
particles, such as protons and neutrons and, hence, all elements of the
periodic system.
"But why does nature have second and third
generations, if these are hardly needed? And are there maybe more generations
of particles?", ask the main authors of the article, Martin Wiebusch and
Otto Eberhardt. At least, the latter question is answered: "There are exactly
three fermion generations in the standard model of particle physics!"
For their analysis, the researchers combined
latest data collected by the particle accelerators LHC and Tevatron with many
known measurements results relating to particles, such as the Z-boson or the
top-quark. The result of the statistical analysis is that the existence of
further fermions can be excluded with a probability of 99.99999 percent (5.3
sigma). The most important data used for this analysis come from the recently
discovered Higgs particle.
The Higgs particle gives all other particles
their mass. As additional fermions were not detected directly in accelerator
experiments, they have to be heavier than the fermions known so far. Hence,
these fermions would also interact with the Higgs particle more strongly. This
interaction would have modified the properties of the Higgs particle such that
this particle would not have been detected. With the exclusion of the fourth
fermion generation the first open question of particle physics is now answered
by the measurements made at the new LHC particle accelerator ring of CERN.
"Within the standard model the number of
fermions is now firmly established," explains Nierste. However, some
interesting questions remain. The properties of the just discovered Higgs
particle still have to be determined and it has to be found out why there is
more matter than antimatter in the universe.
Original Source: Karlsruhe Institute of Technology
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