TUM – Technical University of Munich Menu
A view inside the KATRIN experiment.
A view inside the KATRIN experiment.
Image: KATRIN / KIT
  • Research news
  • Reading time: 2 MIN

First results from the KATRIN neutrino scale

More accurate than expected

Despite their extremely small mass, neutrinos play a key role in cosmology and particle physics. After evaluation of the first measurement results in the Karlsruhe Tritium Neutrino Experiment (KATRIN), it is now clear: The previously unknown mass of the neutrinos must be less than one electron volt. This result is more accurate than previous measurements and raises hopes of discovering new neutrino properties.

Apart from photons, the particles of light, neutrinos are the most common particles in the universe. The discovery of neutrino-oscillation two decades ago proved that – contrary to previous expectations – they have a mass, faint but other than zero.

The lightweight particles thus play a central role in the formation of large-scale structures in the cosmos. Also in the world of elementary particles, the smallest building blocks of the universe, their extremely small mass is of importance: it suggests new physics beyond common models.

Over the next few years, the international KATRIN experiment at the Karlsruhe Institute of Technology (KIT), will determine the mass of these fascinating neutrinos with unprecedented sensitivity. One of the research groups is headed by MaxPlanck@TUM-Tenure Track Professor Susanne Mertens.

In spring 2019, the 150-strong KATRIN team started their first neutrino measurements. The scientists circulated highly pure tritium gas for several weeks and recorded the first energy spectra of electrons from the tritium decay. The international team then set to work to derive the first neutrino mass from the data recorded.

Covert investigations lead the way

In order to obtain three really independent results, three international evaluation groups worked completely independently in parallel. Important additional information was hidden until the last analysis step. Only on the evening of 18 July 2019, all data were unlocked.

Thus, the programs that started simultaneously could compare the measurement data with the model expectation overnight and scan for the characteristic signature of the neutrino mass. All three groups reported identical results, which limited the neutrino mass to a value of less than one electron volt (eV). This means that KATRIN already has the world’s highest neutrino mass accuracy after an initial brief measurement phase.

Susanne Mertens, leader of the group at the Physics Department at the Technical University of Munich and the Max Planck Institute of Physics, coordinated one of the main analyses of the first neutrino mass data. The analysis strategy newly-developed by the TUM group was chosen as main result of this measurement campaign.

Besides the final data analysis her group contributed significantly to the characterization of the background and the calibration of tritium source. “I’m really proud of my team who did a fantastic job to realize this challenging data analysis.”

 

Publications:

First operation of the KATRIN experiment with tritium
M. Aker, K. Altenmüller, M. Arenz et al. arXiv:1909.06069 [physics.ins-det]

An improved upper limit on the neutrino mass from a direct kinematic method by KATRIN
M. Aker, K. Altenmüller, M. Arenz et al. arXiv:1909.06048 [hep-ex]

More information:

In particle physics masses are specified not in kilograms, but in accordance with Einstein's equation: electron volts [eV] divided by the speed of light squared. Electron volts are a measure of energy. This convention is used to circumvent unfathomably small units of mass: 1 eV/c2 corresponds to  kilograms.

The analyses now published use a long-established principle for the direct determination of the neutrino mass: During the radioactive decay of tritium, the resulting electron and an (electron) neutrino share the released energy of 18.6 kiloelectron volts. In extremely rare cases, the electron receives practically the entire energy. For the neutrino, only a tiny fraction of it remains but at least – according to Einstein – the amount E = mc2 of its rest mass.

Of the approximately 25 billion electrons released per second during tritium decay, the KATRIN scientists have investigated only a small sub-set: They filtered out around two million electrons with the appropriate energy spectrum in order to determine the neutrino mass.

KATRIN experimental setup
The KATRIN-Experiment at the MPI for Physics

Corporate Communications Center

Technical University of Munich Dr. Andreas Battenberg
battenberg(at)zv.tum.de

Contacts to this article:

Prof. Dr. Susanne Mertens
Professorship for Dark Matter
Technical University of Munich and
Max Planck Institute for Physics
Föhringer Ring 6, 80805 Munich
susanne.mertens@tum.de
Tel.: +49 89 32354 590

Article at tum.de

A scientist works on the germanium detector array in the clean room of Gran Sasso underground laboratory.

Closing in on elusive particles

In the quest to prove that matter can be produced without antimatter, the GERDA experiment at the Gran Sasso Underground Laboratory is looking for signs of neutrinoless double beta decay. The experiment has the greatest...

As part of her project, Dr. Barbara Lechner observes catalytic processes at atomic level. The green and orange peaks represent platinum clusters each containing 20 atoms on a flat iron oxide surface. This project, along with six others, is to receive funding from ERC Starting Grants.

EU funding for top-level research at TUM

The European Research Council (ERC) has announced that seven of its prestigious ERC Starting Grants will be awarded to scientists at the Technical University of Munich (TUM) this year. The subject matter of the projects...

The Kohnen Station is a container settlement in the Antarctic, from whose vicinity the snow samples in which iron-60 was found originate.

Stardust in the Antarctic snow

The rare isotope iron-60 is created in massive stellar explosions. Only a very small amount of this isotope reaches the earth from distant stars. Now, a research team with significant involvement from the Technical...

Neutrinos können Aufschluss über die inneren Vorgänge der Sonne geben.

Comprehensive assessment of the Sun’s fusion processes

Researchers from the Borexino collaboration have published the hitherto most comprehensive analysis of neutrinos from the Sun's core processes. The results confirm previous assumptions about the processes inside the sun. ...

Das IceCube Lab am Südpol unter den Sternen.

First evidence on the source of extragalactic particles

For the first time ever, scientists have determined the cosmic origin of highest-energy neutrinos. A research group led by Prof. Elisa Resconi from the Technical University of Munich (TUM), provides an important piece of...