Dr. Sebastian Wolfschmidt (in the back) and Christopher Staub Lisa Krügel, UBT
The research objective of Dr Sebastian Wolfschmidt and Christopher Straub is to investigate the structure and long-term behaviour of galaxies. "Since these cannot be fully analysed by astronomical observations, we use mathematical models of galaxies," explains Christopher Straub, a doctoral student at the Chair of Mathematics VI at the University of Bayreuth. "In order to take into account that most galaxies contain a black hole at their centre, our models are based on Albert Einstein's general theory of relativity, which describes gravity as the curvature of four-dimensional spacetime."
Mathematicians and astrophysicists have been researching the properties of such galaxy models for decades, but many open questions remain. To help answer these questions, Straub and Wolfschmidt have implemented a deep neural network, which represents a completely new approach in this field of research. Neural networks are powerful computational models whose structure is inspired by that of the human brain. They are used in the field of artificial intelligence to detect complex structures in large amounts of data. "The neural network can predict which models of galaxies can exist in reality and which cannot," says Dr Sebastian Wolfschmidt, research associate at the Chair of Mathematics VI. "The neural network delivers a significantly faster prediction than the numerical simulations used in the past. This means that astrophysical hypotheses that have been put forward over the past decades can be verified or falsified within a few seconds."
Wolfschmidt and Straub have now presented their findings in the journal "Classical and Quantum Gravity". "We have been working on these issues at the Chair of Mathematics VI in Prof Dr Gerhard Rein's research group since 2019. After various analytical and numerical investigations, we realised about a year ago that the use of machine learning can be particularly helpful for some of our problems. Since then, we have developed the deep neural network described above and already have plans for further applications of similar methods," says Straub.
The calculations of the Bayreuth mathematicians were carried out by the supercomputer of the "Keylab HPC" at the University of Bayreuth and the project emerged from a collaboration with the Chair of Applied Computer Science II - Parallel and Distributed Systems.
Contact for scientific information:
Christopher Straub
Doktorand am Lehrstuhl für Mathematik VI
Mail: christopher.straub@uni-bayreuth.de
Phone: +49 (0)921 55-3284
Original publication:
Straub, C., Wolfschmidt, S., Predicting the stability of star clusters in general relativity, Classical and Quantum Gravity (2024). https://doi.org/10.1088/1361-6382/ad228a
