MessageToEagle.com - Neutrinos are very elusive. They are impossible to see and difficult to detect.
Neutrinos, which have unusual properties, have extremely weak interactions with all other particles.
To capture these elusive neutrinos with unusual properties, physicists conduct many experiments.
They also want to determine their mass.
Now scientists of the GERDA collaboration obtained new strong limits for the so-called neutrino-less double beta decay,
which tests if neutrinos are their own antiparticles.
Click on image to enlarge
Shining example. The GERDA experiment at the Gran Sasso lab in Italy has all but ruled out earlier claims for neutrinoless double-beta decay.
Besides photons, neutrinos are the most abundant particles in the Universe. They are often called `ghost
particles’, because they interact extremely weakly with matter.
They are therefore an invisible, but very important
component of the Universe, which could carry altogether as much mass as all other known forms of matter, albeit
traveling almost at the speed of light over fantastic distances.
Their tiny masses have also important consequences for the structures in the Universe and they are the driving
element in the explosion of Supernovae. But their most remarkable and important property has been proposed by
Ettore Majorana in the 1930ies:
Unlike all other particles that form the known matter around us, neutrinos may be their own antiparticles.
Particle and antiparticle are distinguished by their charges. The positron, for example, the antiparticle of
the negatively charged electron, is positively charged. The neutrino, on the other hand, is electrically neutral –
the prerequisite for the ability of being its own antiparticle.
If this is really the case is being investigated by the GERmanium Detector Array (GERDA) 1400 meters down
in Italy's Gran Sasso National Laboratory.
To this end, GERDA examines so-called double beta decay processes in the germanium isotope Ge-76 with and without
emissions of neutrinos – the latter being a consequence of the Majorana properties.
Gran Sasso National Laboratories - GERDA - Germanium Detector Array, Italy
In normal beta decay, a neutron inside a nucleus decays to a proton, an electron and an antineutrino. For nuclei
like Ge-76, normal beta decay is energetically forbidden, but the simultaneous conversion of two neutrons with the
emission of two antineutrinos is possible and has been measured by GERDA recently with unprecedented precision.
This is one of the rarest decays ever observed with a half-life of about 2*1021 years, which is about 100 billion
times longer than the age of the Universe.
If neutrinos are Majorana particles, neutrino-less double beta decay should also occur at an even lower rate. In
this case, the antineutrino from one beta decay is absorbed as neutrino by the second beta-decaying neutron, which
becomes possible if neutrinos are their own antiparticle.
In GERDA germanium crystals are both source and detector. Ge-76 has an abundance of about 8% in natural germanium and its fraction was
therefore enriched more than 10-fold before the special detector crystals were grown.
Searching for a needle in a haystack is trivial compared to the detection of double beta decay, since environmental
radioactivity is a background occurring at a rate at least a billion times higher than double beta decay.
The GERDA detector crystals and the surrounding detector parts were therefore very carefully chosen and processed.
Data taking started in fall 2011 using eight detectors the size of a tin can and weighing two kilograms each.
Subsequently, five additional newly designed detectors were commissioned. Until recently, the signal region was
blinded and the scientists focused on the optimization of the data analysis procedures. The experiment has now completed i
ts first phase.
The analysis in which all calibrations and cuts had been defined before the data in the signal region were processed,
revealed no signal of neutrino-less double beta decay in Ge-76 which leads to the world’s best lower limit for the
half-life of 2,1*1025 years. Combined with information from other experiments, this result rules out an earlier
claim for a signal by others.
The new results from GERDA have interesting consequences for the knowledge on
neutrino masses, extensions of the standard model of elementary particle physics, astrophysical processes and cosmology.
The next steps for GERDA will be to add additional newly produced detectors effectively doubling the amount of Ge-76.
Data taking will then continue in a second phase after some further improvements are implemented to achieve even
stronger background suppression.
Space-Time Crystal Computer That Can Outlive Even The Universe Itself!
It may seem strange to think something can survive even the death of the Universe,
but that could actually be possible as a result of the laws of quantum physics.
Scientists are now suggesting a new blueprint for a device,
known as a time crystal, that can theoretically continue to function as a
computer even after the universe cools to absolute zero.
Biometrics: Eye-Scanners Can Be Fooled
Iris scanning technologies allow people to use their eyes to prove their identify. S
canning your iris has been considered a very good security tool, but now it turns out it is actually possible to fool eye-scanners!