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The GERDA experiment

The GERDA experiment is investigating whether the neutrino is its own antiparticle. The search is on for so-called neutrinoless double-beta decay, which has never been observed before. One isotope which could exhibit this extremely rare radioactive decay is germanium-76. The experiment is therefore based on germanium detectors which have been enriched with this isotope.

Neutrinoless double-beta decay involves the conversion of two neutrons into two protons and two electrons. Two neutrinos are also released in this process, but they can annihilate each other – provided they are their own antiparticles. This decay therefore exists only if

  • neutrinos and their antiparticles are identical
  • and have a mass.

The GERDA experiment incorporates a total of 36 kilograms of detector material. This corresponds to around 1026 germanium-76 nuclei in total. With this number of nuclei, it should prove possible to detect this decay within a few years if its half-life is 1026 years or less.

Should GERDA measure a small number of the hypothetical and extremely rare decays, this would be a possible answer to the question: Why the universe contains matter, but no longer contains any antimatter – the key to our existence. Moreover, the physicists could draw conclusions about the mass of the neutrino.

Underground environment with extremely low radiation

As neutrinoless double-beta decay is so rare, the GERDA experiment has to have the best possible protection against disturbing influences. It is therefore located in the Gran Sasso underground laboratory in Italy, where 1.4 kilometers of mountain rock shield it against cosmic radiation from space.

The germanium detectors are furthermore in an extremely clean environment: in a tank made of specially selected steel with a very low radiation rate which is filled with liquid argon. This vessel is in turn housed in a ten-meter-diameter tank filled with ultrapure water.

The GERDA collaboration has around 120 members from 16 institutes in six European countries, including the Max Planck Institutes for Physics (MPP) and Nuclear Physics. The GERDA Group at the MPP was responsible for constructing the cleanroom above the cryostat, and for developing and constructing the infrastructure used to lower the detectors into the argon tank, the so-called lock system.

Further information on the GERDA group

News releases

04/04/2017
Preparation of the GERDA experiment: Lowering the germanium detector array into the liquid argon tank  - view from top. (photo: M. Heisel/GERDA collaboration)

Scientists report an important milestone in the search for neutrinoless double beta decay (0vββ). As published in Nature, the GERDA experiment succeeded in reducing the radiation background to an extent that there are practically no disturbing signals any more. If the germanium detectors now measure...

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07/11/2016
View from below into the GERDA experiment: Seen here are the cables of germanium diodes and the shielding.

Is the neutrino its own antiparticle? How large a mass do neutrinos have? Scientists working on the GERDA experiment want to find answers to these questions. The first results of the second measurement phase, which began in December, were recently presented at the Neutrino 2016 conference in London.

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02/01/2016

Stefan Schönert, Professor for Experimental Astroparticle Physics at the Technical University of Munich (TUM), has been named a Max Planck Fellow at the MPP, where he will do research in the area of dark matter and neutrino physics. The Fellow Program of the Max Planck Society (MPG) has the goal of...

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Group members

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Caldwell, Allen, Prof. Dr.

Director 529

Fischer, Felix

PhD Student 280

Gooch, Christopher

Engineering 242

Hayward, Connor

PhD Student 764

Kicsiny, Peter

Student 415

Kneißl, Raphael

PhD Student 415

Majorovits, Béla, PD Dr.

Scientist 262

Schulz, Oliver, Dr.

Scientist 521

Zsigmond, Anna Julia, Dr.

Scientist 337

Events and meetings

Key publications

Improved Limit on Neutrinoless Double-β Decay of 76Ge from GERDA Phase II
GERDA Collaboration
Phys. Rev. Lett. 120 (2018) 132503
arXiv:1803.11100

Upgrade for Phase II of the Gerda experiment
GERDA Collaboration
Eur. Phys. J. C78 (2018) 388
arXiv:1711.01452

Background-free search for neutrinoless double-β decay of 76Ge with GERDA
GERDA Collaboration
Nature 544 (2017) 47
arXiv:1703.00570

Limits on uranium and thorium bulk content in GERDA Phase I detectors
GERDA Collaboration
Astropart. Phys. 91 (2017) 15
arXiv:1611.06884