A nuclear waste repository must seal in radioactive waste safely for one million years. Researchers currently have to study nuclear waste repositories in real underground laboratories but a virtual laboratory will soon simplify their work.
A potential site’s real suitability as a nuclear waste repository can only be analyzed once such a repository has been designed, planned and studied together with its equipment modules. Various complex physical and chemical processes take place in a nuclear waste repository—the rock may be heated by the waste stored and gases may develop. Until now, researchers have studied such processes in underground laboratories such as the ones in Mont Terri in Switzerland or in Äspö in Sweden as well as in France and Belgium. The period of a study is limited, though, because none of the tests can be conducted for more than a few years.
The most important German nuclear waste repository research organizations—the Gesellschaft für Anlagen- und Reaktorsicherheit GRS, the Federal Institute for Geosciences and Natural Resources BGR and DBE Technology GmbH—therefore need to supplement real underground laboratories. They contracted researchers at the Fraunhofer Institute for Factory Operation and Automation IFF in Magdeburg the world’s first virtual underground laboratory, VIRTUS. A software platform is the virtual laboratory’s central component. It realistically represents all of the conditions there: The types of rocks in the soil and the physical or chemical processes that take place in a deep geological repository. This enables researchers to perform virtual experiments and to review plans and sites for nuclear waste repositories down to the smallest detail.
In a first step, the researchers recreate site’s geological formations. Since concrete sites for nuclear waste repositories do not exist yet, they work with a generic model—rock formations are structured realistically but do not recreate any real site. “After all, the first task is to develop the system and to test VIRTUS’s performance on the basis of initial calculations,” says Steffen Masik, engineer at the Fraunhofer IFF. Users can lay out a virtual deep geological repository in this rock formation. They have a great deal of freedom in the process: They can specify the depth, area, height and width of the repository. They can also import a repository complex created beforehand and specify the locations of boreholes and adits in which radioactive waste will be stored.
Once they have created a repository complex, the researchers can commence their studies—just like in a real underground laboratory and select an area of the deep geological repository. A special interface transfers the location selected and the repository data to a simulator, which computes, for instance, rises in temperature in the repository caused by the radioactive waste. The results are visualized in VIRTUS. Users can also display cross sections of the rock together with the temperatures there. Mechanical stresses and thus the probability of crack formation can also be computed. Researchers can closely examine permeability to water or other liquids and gases. VIRTUS displays all of the calculations together with the geological model. “The software visualizes the computed thermal, hydraulic and mechanical processes in a nuclear waste repository as well as their complex interactions,” says Klaus Wieczorek, who works in the division of nuclear waste repository safety research at GRS and is heading the VIRTUS project.
VIRTUS is still under development at present. A first prototype is supposed to be publicly accessible at the end of April: In the future, visitors to the large, 360 degree projection system at the Virtual Development and Training Center VDTC in Magdeburg will be able to see the workings of a nuclear waste repository and the simulation results.