Photo: UHH/MIN/Fuchs The new group is under the direction of Georg Rohringer.
Theoretical physicists need easily calculable theories and models with which material properties can be predicted: Is the substance, for example, an electrical conductor or an insulator? Is the substance magnetic? And how do they reflect light waves’ The difficulty of the various theories lies in the fact that they are supposed to represent reality as accurately as possible and still have to be greatly simplified, because otherwise even supercomputers would be overwhelmed by the calculation. The result is that many similar theories have been developed over the past ten years, but they only work well with a few materials.
The new Emmy Noether Group will first carry out a systematic comparative analysis of existing theories and will provide an overview of what each theory does. In the second step, the physicists will develop a new method to ensure the comparability of the different theories. "Different theories in physics should provide consistent results for the same problem," says Dr. Georg Rohringer. "But this is not the case with many current theories, and we want to change that."
Based on the preliminary work, the Emmy Noether team intends to propose a new general theory in the third step, which avoids the problems of the current methods and should be valid for as many material classes as possible. Such a model would not only be a breakthrough in basic research, it would also have great technological relevance. "Today, we are faced with the big question of how we can maintain our standard of living while still protecting the environment and climate. This is not easy, because we need energy," says Rohringer.
"One solution would be the long-known superconductivity, the loss-free storage and transport of electrical energy." With superconductivity, wind and solar energy could be stored for longer periods of time without any losses. The current problem with superconductivity is that the materials used have to be cooled with liquid nitrogen, which means that more energy is used than is saved. "One vision of our work would be that the new theories could be used to calculate previously unknown materials in which superconductivity would also be possible at higher temperatures, ideally at room temperature," says the physicist.
