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Intermediate mass black holes (IMBH) should be linking observed stellar black holes and supermassive black holes, but their formation mechanisms are still debated. Young and dense massive star clusters are promising environments for the formation of such black holes through collisions. An international team lead by MPA researchers has presented novel realistic simulations of star clusters, where these missing links form by rapid collisions of stars and black holes. The study also predicts an IMBH formation channel by the merging of black holes in a mass regime, which is excluded by stellar evolution models. In this “mass gap” a black hole merger has indeed been observed recently by the LIGO/Virgo gravitational wave collaboration.

The formation of intermediate mass black holes in young massive star clusters

Where are the baryons? This question naturally arises as the predicted abundance of baryons in the universe - the basic building blocks of all elements in the periodic table – do not agree with observations of the intergalactic medium. Locating the missing baryons will help us to not only better understand the formation and evolution of galaxies, but also to better constrain possible extensions of the current standard model of cosmology. MPA researchers have turned to a novel approach in modelling the galaxy distribution to optimize measurements of the kinematic Sunyaev-Zel'dovich effect, an emerging tool to probe the distribution of baryons in galaxy clusters.

Optimal measurements of the kinematic Sunyaev-Zel'dovich effect reveal missing matter

How can machine learning methods help us understand our tangled cosmic web? A new study presents a ‘deep learning’ framework to shed light onto the physics of the formation of dark matter halos. The results show that spherical averages over the initial conditions of the Universe carry the most relevant information about the final mass of halos.

‘Deep learning’ provides insights into cosmological structure formation

The first all-sky survey performed by the eROSITA X-ray telescope on-board the SRG observatory has revealed a large hourglass-shaped structure in the Milky Way. These “eROSITA bubbles” show a striking similarity to the Fermi bubbles, detected a decade ago at even higher energies. The most likely explanation for these huge features is a massive energy injection from the Galactic centre region in the past, leading to shocks in the hot gaseous halo around our galaxy.

SRG/eROSITA detects large-scale X-ray bubbles encompassing the Fermi bubbles

Radio telescopes observe the sky in a very indirect fashion. Sky images in the radio frequency range therefore have to be computed using sophisticated algorithms. Scientists at the MPI for Astrophysics have developed a series of improvements for these algorithms, which help to improve the telescopes' resolution considerably.

Algorithmic improvements for radio interferometry

Dark matter is the most abundant matter component in the universe. But while it influences all structure in the universe, its nature is still unknown. Among the many candidates is ultra-light dark matter, the lightest possible candidate for dark matter, which been receiving a lot of attention recently, as this might be probed by current and future experiments. MPA researchers have written a review on the current status of these models and their search for observational markers, introducing a division into three classes and showing how the rich phenomenology of this leading candidate for dark matter could help answer the question of what dark matter really is.

The light and fuzzy side of dark matter

Emeritus Scientific Member and former Director of the Max Planck Institute for Astrophysics

Rudolf Kippenhahn (24.5.1926 – 15.11.2020)

News at MPA

Note due to corona: Contacting MPA

To contain the spread of corona virus infections, the MPA has enacted certain changes to protect its employees. For the time being, the MPA will not offer public events, and its staff will not undertake travel or attend conferences. Meetings will primarily be held via video conferencing.
It might be difficult to reach some staff members by telephone, please use Email instead. Mail continues to be received. Please note, however, that there might be some delays in getting a response.
For information about MPG research on the Corona virus, please see here:

Simona Vegetti now head of Lise Meitner Excellence Group

February 01, 2021

The Max Planck Society has appointed Simona Vegetti at MPA to head a Lise Meitner Excellence Group. Simona Vegetti will use strong gravitational lensing observations to measure the abundance and structural properties of dark matter haloes and thereby provide clean observational constraints on the nature of dark matter. As part of the programme, the group is endowed with an internationally competitive budget for material and human resources.

Tempestuous life of galaxy clusters: X-ray view on the Coma cluster with SRG/eROSITA

January 27, 2021

Galaxy clusters are dynamic systems that grow by continuously accreting large and small chunks of matter. This accretion process should give rise to a rich substructure in the dark matter distribution within the clusters and to shocks and “cold fronts” in the hot baryonic gas. Recent SRG/eROSITA observations provided an unprecedented X-ray view of the Coma cluster, revealing intricate signatures of the merger process, which are predicted by numerical simulations.

April 2021

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"Chemistry as a diagnostic of star formation"

from 14:00 to 15:00

"A large study to explain the size-luminosity relation in sub-structured protoplanetary disks"

from 10:00 to 11:00

"ALMA-IRDC: Dense gas mass distribution from cloud to core scales"

from 10:30 to 11:30

"The origin and evolution of carbon in the Galactic bulge"

from 12:00 to 13:00

"Deep learning insights into cosmological structure formation"

from 15:30 to 16:30

"Physics of high Q microresonators: From Quantum Mechanics of Macroscopic Objects to Chipscale Frequency Combs"

from 17:15 to 18:30

Title 1: "Can uncertainties in the evolution of massive stars explain properties of gravitational wave progenitors?" and Title 2: "Gamma Rays from Fast Black-Hole Winds"

from 15:00 to 16:00

"Changing paradigms in planet formation”

from 11:00 to 12:00

"Electroweak bubble wall velocities" (prelim.)

from 14:00 to 15:00

"The interstellar medium of high redshift galaxies"

from 15:15 to 16:15

"Pair-instability Supernovae"

from 11:00 to 12:00

Upcoming seminars

"Pair-instability Supernovae"

Apr 23, 2021 11:00 - 12:00

online - zoom

Sub-Saharan Africa Astronomy Summer School

Sep 5, 2021 - Sep 17, 2021

Entebbe - Uganda

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About MPA

Structure

Managing Director
Prof. Dr. Volker Springel

Scientific Members, Kollegium, Directors
Dr. Selma E. de Mink
Prof. Dr. Guinevere Kauffmann
Prof. Dr. Eiichiro Komatsu
Prof. Dr. Volker Springel

Emeritus Directors
Prof. Dr. Wolfgang Hillebrandt
Prof. Dr. Rashid Sunyaev
Prof. Dr. Simon White

External Scientific Members
Prof. Dr. Rolf-Peter Kudritzki
Prof. Dr. Werner Tscharnuter

Head of the administration
Hendrik Wanger

Contact

Press and Public Relations
Dr. Hannelore Haemmerle
Phone: 089 30000-3980
Cornelia Rickl
Phone: 089 30000-2201
Dr. Hans-Thomas Janka
Phone: 089 30000-2228

email: pr@mpa-garching.mpg.de

Max Planck Institute for Astrophysics, Garching
Karl-Schwarzschild-Str. 1
Postfach 1317
D-85741 Garching, Germany

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