Physicists take cover:
New underground laboratory for astroparticle research
20.05.2009, Press releases
The Physics Department of Technische Universitaet Muenchen currently builds a new underground laboratory for astrophysical experiments. After its completion in late 2009 it will provide over 130 square metres of laboratory area and will be open to other European work groups within the framework of future major projects in astroparticle physics. Completion of the laboratory is planned for the end of 2009.
A core topic of astroparticle physics is neutrino research. Neutrinos are generated during fusion reactions inside stars and during stellar explosions, but were also formed during the dawn of the universe. Another core topic is dark matter: Hitherto unknown particles also come into consideration as possible candidates for this form of matter, which makes up approximately 80 percent of the total matter of the universe.
The Technische Universität München and the Excellence Cluster „Universe“ are making an important contribution to astroparticle physics in Germany with the new laboratory. The UGL2 serves as a development and test station for detection equipment, with which these particles can be detected. The detectors are used in large-scale research projects throughout Europe. These include international collaborations such as the experiment to build a search for dark matter CRESST, the future EURECA experiment, Double Chooz in France, and a future 50kt detector for neutrino astronomy.
An apparatus for the testing of low-temperature detectors is planned for the new UGL which can be operated at one hundredth of a degree above absolute zero, for example for the detection of dark matter particles. An additional main focus of the work in the UGL is the development and testing of liquid scintillators, which emit light signals as soon as they detect a sought-after particle. Work, which has been conducted already in the existing much smaller laboratory.
Neutrinos occur extremely frequently on the earth, nevertheless they are extremely difficult to verify as they are neutral and rarely interact with their environment. The detectors must therefore be highly sensitive and react specifically to the sought-after particles. Furthermore, interfering background occurrences caused by muons must be suppressed. These particles are generated when cosmic rays strike the atmosphere.
This is why the development of new detection methods takes place in a protected environment. The UGL2 will be installed below an earth wall of six metres, which reduces the number of muons per square metre per second by approximately one third. Other components of the interfering cosmic radiation are blocked virtually completely.
Kontakt: presse@tum.de
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