© Götz Walter, Biermann-Jung Kommunikation & Film.
Studying the fundamentals of infinite symmetry Groups are of fundamental importance throughout mathematics, and new analytical methods are being developed to gain deeper insights into unresolved questions in the field. Professor Andreas Thom tells us about the work of the GrDyAp project in connecting group theory, functional analysis, and the theory of dynamical systems, which could open up new perspectives on long-standing mathematical problems. The study of symmetry is at the heart of pure mathematics, with researchers building on the existing foundations of group theory to approach long-standing problems in the field. Groups arise as symmetries of objects and are thus of fundamental importance across different branches of mathematics, now researchers in the ERC-funded GrDyAp project are looking deeper into the subject. “The project tries to connect group theory, functional analysis, and the theory of dynamical systems,” says Andreas Thom, Professor of Mathematics at Technische Universität Dresden, the project’s Principal Investigator. This work also touches on several other areas within the pure mathematics field. “My research is solely in pure mathematics, but it brings together different branches of pure mathematics,” continues Professor Thom. A group itself can be understood as a type of algebraic structure consisting of symmetries which can act on an object, like a geometric figure or something more complicated. For example, a cube has 24 symmetries which act on the cube; this may on the surface seem difficult to fully understand, but things get clearer when one looks at the cube in more detail. “Each symmetry of the cube has a concrete meaning. An abstract group cannot be understood directly, precisely because a natural object is missing, on which it acts by
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symmetries (whose symmetries it is). Now, in geometric group theory, such an object is constructed — the Cayley graph,” explains Professor Thom. Symmetries can explain complex behaviour of phenomena, ranging from material sciences to quantum physics to everyday objects, says Professor Thom. “Why is a dice fair? Because it has so many symmetries that make it obvious that each side has equal probability,” he points out.
Infinite symmetry groups The major goal in the project now is to study infinite symmetry groups, with Professor Thom and his colleagues looking to develop
novel methods to approach some of the major challenges in infinite group theory. Groups can be found throughout mathematics, and while significant progress has been made in classifying some types of groups, notably finite symmetry groups, Professor Thom says that infinite symmetry groups are particularly challenging. “Infinite groups are harder to study because one cannot write down a complete multiplication table. One has to understand them by other means, for example via the geometric object whose symmetries they describe,” he outlines. “One such object is the Cayley graph, but frequently there are also even more geometric objects, such as
© Götz Walter, Biermann-Jung Kommunikation & Film.
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