For the Earth and in Space: New Measuring Device for Monitoring Radiation
PTB researcher Marlies Luszik-Bhadra and her team receive this year's Technology Transfer Prize of the IHK Braunschweig (CCI Braunschweig)
23.11.2007
The new personal dosimeter for mixed radiation fields is the smallest of its kind, and with a weight of approx. 80 grams also the lightest. (photo: PTB)
How high is the current radiation exposure for the crew of the ISS? In future, direct-readout dosimeters such as that developed by the physicist Marlies Luszik-Bhadra will provide a clear answer. In the photo: A humanoid "phantom" (Matroshka) on the outside of the ISS wears a vest with various dosimeters - for reasons of testing. (photos: ESA)
Natural neutron radiation surrounds us constantly - caused by the collision of high-energy cosmic particles with the molecules of our Earth's atmosphere. The intensity of this neutron radiation increases thereby with height and is especially relevant for flights, so that the radiation dose of flight personnel is continuously monitored. In contrast to this, humans themselves are responsible for the artifical neutron radiation on the ground. It is found in medical applications such as in tumour therapy, is used in non-destructive material testing, and is always present in nuclear power plants.
In general, however, neutron radiation seldom occurs alone. In most cases it is even the smaller component - above all in comparison to photon radiation (gamma radiation). A measuring device which includes both radiation components simultaneously is thus an ideal tool to monitor radiation-critical environments.
The personal dosimeter developed by Luszik-Bhadra, together with the Synodys group, is able to measure both radiation components in a handy and moreover very light device. It is the currently smallest dosimeter for mixed neutron/photon radiation fields. Compared to conventional laboratory electronics, the construction is smaller by a factor of 1000. The innovative idea thereby is in the interior construction of the detector. Whereas up to now, several semiconductor detectors have always been used for the construction of a neutron dosimeter, the new dosimeter gets by with a single detector surrounded by several thin absorber layers.
Hence the dosimeter is open to diverse fields of application: from medicine to nuclear technology and also to space-related assignments. For the crew of the International Space Station ISS - a place with especially intensive radiation - the measurement of the current radiation exposure is of particular importance. Up to now, passive dosimeters have been used here which can only be evaluated later on the Earth. A test application of the new direct-readout dosimeter is now being discussed with the European Space Agency ESA.
Further information:
Dr. Marlies Luszik-Bhadra
Department "Neutron Radiation"
Physikalisch-Technische Bundesanstalt (PTB)
Bundesallee 100, 38116 Braunschweig
Tel.: +49-531-592-6520
E-mail: marlies.luszik-bhadra(at)ptb.de