The Würzburg-led research unit "Relativistic Jets in Active Galaxies" has been investigating the powerful plasma beams emitted by supermassive black holes since 2021. Now the DFG has extended its funding.
At the center of almost every large galaxy lies a supermassive black hole - an object with a mass millions to billions of times that of our sun. While these cosmic giants are known for their unimaginable gravitational pull, under certain conditions they can not only devour matter, but also hurl it back into space in the form of powerful plasma beams.
Known as "relativistic jets," these phenomena are collimated streams of high-energy particles that shoot out of the immediate vicinity of the black hole at nearly the speed of light. They radiate across the entire electromagnetic spectrum and can reach distances far beyond their home galaxy. "Research into these jets is of fundamental importance because it touches on profound questions of astrophysics and cosmology," says Matthias Kadler.
Kadler is Professor of Astrophysics at the Chair of Astronomy at the University of Würzburg and spokesperson for the research unit "Relativistic Jets in Active Galaxies" (FOR 5195), which is funded by the German Research Foundation (DFG). It brings together numerous leading research institutions from Germany and European partner groups in this field; the University of Würzburg coordinates the network.
A recognition of the outstanding scientific work
For a good four years, the network has been working to deepen knowledge about these jets - with success: the DFG has now extended the research unit's work for another four years. It is providing about 4.75 million euros for this purpose. "The extension is a recognition of the outstanding scientific work in our research unit and proof of the high potential of this research topic," says Matthias Kadler.
Over the past four years, the members of the research unit have made significant progress in answering numerous questions about the nature of jets. For example, they were involved in the groundbreaking observations of the Event Horizon Telescope (EHT). These led to the world's first images of black hole shadows and the associated "launch pads" of cosmic jets.
However, the unit's work is not yet complete - quite the contrary: "With our findings, we have laid the foundation for new, even more ambitious goals," says Matthias Kadler. He is therefore confident that the group will continue to discover new and exciting details about jets in the coming years.
The participating scientists are pursuing three key objectives:
1. Understanding the origin of jets: How exactly do these jets form directly in the immediate surroundings of black holes, and what gives them their enormous energy and precise alignment?
2. Analyzing jet composition and radiation: What are these jets made of, and what physical processes cause them to shine so brightly - from radio waves to high-energy gamma and particle radiation?
3. Assessing the influence of jets on the universe: How do these plasma beams shape the development of entire galaxies and galaxy clusters, for example by regulating star formation and heating up their surroundings?
For the coming funding period, the team has set itself new priorities that aim to push the boundaries of what is currently known:
• Neutrino astronomy: The researchers want to investigate the connection between jets and high-energy neutrinos.
• Cosmological evolution: A particular focus is on the role of jets in the early universe. Due to their extreme brightness, jets serve as unique beacons for tracing the evolution of galaxies and black holes over billions of years.
• New and improved telescopes: The research unit is actively involved in the development and improvement of state-of-the-art telescopes such as the Bavarian Wetterstein Millimeter Telescope, the European research infrastructures Low Frequency Array (LOFAR) and Cherenkov Telescope Array (CTA), and the worldwide Global Millimeter VLBI Array (GMVA).
A Germany-wide Network of Experts
The research unit brings together expertise from various fields of astrophysics - from theoretical modeling and computer simulations to observations with the world's best telescopes. Five of the research unit's ten subprojects are led at JMU Würzburg. In addition to Kadler, Professors Sara Buson and Karl Mannheim are involved, as well as junior research group leader Dr. Christian Fromm.
Other institutions funded by the network include the Universities of Erlangen-Nuremberg, Hamburg, and Heidelberg, the Max Planck Institutes for Radio Astronomy in Bonn and Astronomy in Heidelberg, the Leibniz Institute for Astrophysics Potsdam, and the German Electron Synchrotron (DESY) in Zeuthen. Internationally, the Open University in the UK, IA-FORTH in Greece, and the University of Valencia are closely involved in the research.
DFG Research Unit
DFG Research Units are a key instrument of German research funding. They enable leading researchers to work together on complex scientific tasks. The funding is intended to help provide the necessary personnel and material resources for close cooperation in the medium term.
