Small-scale dynamos are thought to explain how weak magnetic fields in
the early universe were amplified to the strengths we observe in
galaxies today. While this process is usually associated with the early
stages of galaxy formation, mergers between mature galaxies can trigger
bursts of turbulence that reignite dynamo activity. A key question is
how quickly the magnetic energy grows during these events. Seminal
theories suggest this process could be too slow to matter – taking
longer than the age of the universe – because growth is limited by
slow diffusion. However, recent works have begun to challenge this idea.
In this talk, I will present new simulations that explore this question
and offer insight into the processes that regulate magnetic growth in
galaxies.
Quasars as sub-milliarcsecond lighthouses: using VLBI to chart the Milky Way
Special Colloquium
Dr. Sasha Plavin
ORATED
Black Hole Initiative, Harvard University
Interstellar scattering enlarges the apparent size of compact radio
quasars, and VLBI resolution lets us measure this broadening over the
whole sky. By analysing thousands of archival VLBI observations, we
have
compiled an all-sky catalogue of quasar scattering sizes and produced a
corresponding Galactic scattering map. Complementary deep, multi-band
campaigns on a few highly scattered sources are under way, already
revealing individual screens and constraining their locations,
turbulence spectra, and inner scales. I will present the latest results
from the all-sky VLBI mapping of the Milky Way, and discuss the ongoing
deep follow-ups, placing the VLBI view in the context of other tracers
of the ionised interstellar medium.
Jet precession and variability in M81*
Master Colloquium
Prathamesh Ingale
ORATED
MPIfR
Active galactic nuclei are some of the most powerful sources in the
cosmos and M81*, a nearby low-luminosity AGN, offers a unique window
into their jet dynamics. In this thesis, we explore compelling evidence
of jet precession and flaring variability in M81* using over 60
high-resolution VLBI observations (VLBA, EVN) and complementary
multi-frequency monitoring with the Effelsberg radio telescope. Our
analysis traces the jet's evolving orientation and disentangles its
variability across time and frequency, providing new insights into AGN
behavior in the sub-Eddington regime.
The Cold Neutral Medium in the Milky Way ISM with ASKAP
Special Colloquium
Dr. Callum Lynn
ORATED
Australian National University
Observations of neutral hydrogen (HI) within galaxies are an important
tracer to probe the evolution of complex physical processes that occur
within the interstellar medium (ISM). With its close proximity, the gas
of the Milky Way provides us the ideal laboratory to investigate these
processes and the eventual formation of molecular clouds at scales
beyond the sub-grid resolution of most numerical ISM simulations.
Observations of this calibre are vital to test our current theoretical
understanding of the turbulent cascade and formation of cold gas. The
SKA precursor, ASKAP, has observed the Milky Way foreground towards the
Magellanic System in unprecedented detail, with its current spatial
resolution and unbiased detection manner cataloguing hundreds of Milky
Way HI absorption sources within a relatively small field of view,
rivalling the combined catalogue of previous detections across the
entire sky. I will present recent work done by the GASKAP-HI
Collaboration using these latest advancements in source density made by
the GASKAP-HI survey. More specifically I will discuss the unique
prospect of calculating the structure function of optical depth and
other HI properties across a filamentary region, to better understand
the spatial structure of the cold neutral medium and its formation. I
will also discuss the correlation between HI and dust and how the
increased background source density has enabled the ability to detect
higher temperature phases of gas through stacking spectra to improve the
signal-to-noise beyond the current observational sensitivity of ASKAP.
Chasing coherent radio emission from binary neutron star mergers with LOFAR2.0
Main Colloquium
Dr. Antonia Rowlinson
ORATED
University of Amsterdam and ASTRON
Binary neutron star mergers are exciting high energy phenomena in our
Universe, leading to gravitational wave events, gamma-ray bursts and
kilonovae. We know the majority of gold and other heavy elements are
produced by these events. However, a key outstanding question is: What
is the remnant formed by these mergers? A black hole or an even more
massive neutron star? If it is a neutron star, it will be spinning at
near break-up velocities with a huge magnetic field – a newborn
magnetar. By studying emission in X-rays and optical following these
mergers, there are hints that we have seen the formation of magnetars.
The newly formed magnetar is predicted to give bright, short duration,
flashes of coherent radio emission soon after its formation.
I am using LOFAR to chase these coherent signals following binary
mergers and, excitingly, we have our first candidate detection. To
firmly associate candidates with poorly localised binary mergers, we
also require deep transient surveys with LOFAR. In this colloquium, I
will describe the magnetar central engine model for binary neutron star
mergers and outline the key results from our fast transient surveys in
the image plane with LOFAR. Looking towards LOFAR2.0, I will describe
our efforts to fully automate fast transient image plane searches to
find coherent radio transients from multiple progenitor systems.
Finally, I will introduce the upcoming AARTFAAC2.0 and outline the
exciting results we hope to obtain from it.
LADUMA First Data Release: What we have found so far
Special Colloquium
Dr. Abhisek Mohapatra
ORATED
University of Cape Town
One of the fundamental questions in astrophysics is how galaxies form
and evolve across cosmic time. At the heart of this lies neutral
hydrogen (HI) — the raw material for star formation and a key
component of the baryon cycle. With powerful new radio telescopes like
MeerKAT, we can now push the frontier beyond the local Universe. In this
talk, I’ll introduce the LADUMA survey — Looking at the Distant
Universe with the MeerKAT Array — the deepest HI survey from the
MeerKAT. LADUMA focuses on a single field, with 300 hours of L-band
observations (probing HI to z < 0.6) and a planned 3000 hours in
UHF-band (extending to z ~ 1.4). From our first 127 hours of L-band
data, we have detected HI in about 240 galaxies out to redshift ~0.5.
These direct detections allow us to trace the distribution and evolution
of HI in galaxies over time. By combining LADUMA’s deep HI data with
rich multi-wavelength surveys, we’re beginning to piece together how
galaxies acquire, retain, and deplete their gas. I’ll share some of
our initial results and discuss what they reveal about the role of HI in
galaxy evolution, and how LADUMA is poised to transform our view of the
distant Universe.
Characterising Pulsar Emission Widths
Master Colloquium
Sanket Bangar
ORATED
MPIfR
Pulsars are highly magnetized, rapidly rotating neutron stars that emit
beams of electromagnetic radiation. The evolution of the average
emission widths with frequency provides valuable insights into the
magnetospheric structure and emission physics of pulsars. Traditional
width metrics, such as W50 and W10, often fail to capture the true
extent of the emission region, especially in profiles with
low-intensity wings or multiple components. To address this, we have
developed a novel algorithm, \texttt{PsrWid}, designed to
systematically determine emission widths across a wide frequency range.
The algorithm utilizes Gaussian Process Regression to model the pulse
profile without assuming a predefined functional form, allowing for a
clean separation of signal and noise. The on-pulse region is then
identified using the Kneedle algorithm, which locates the knee point in
the cumulative distribution of log-intensity, providing a robust
thresholding mechanism.
We applied PsrWid to pulse profiles of 1271 pulsars observed with
MeerKAT as part of the Thousand-Pulsar-Array (TPA) program, conducting a
statistical analysis of pulse widths and their correlation with pulsar
properties, particularly spin period and magnetic field strength. As a
case study, we investigate PSR B0355+54, analyzing its pulse profile
evolution over a wide frequency range (102 MHz - 72 GHz) using new
observations from the Effelsberg 100-m radio telescope alongside
archival data from the European Pulsar Network (EPN). In addition,
polarization analysis reveals that while the integrated position angle
(PPA) swing deviates from the Rotating Vector Model (RVM), averaging
only highly linearly polarized single pulses recovers the expected
S-shaped swing, offering insight into the underlying emission geometry.
Neural Network-Based Radio Frequency Interference Mitigation for Wide-band Timing Analysis of PSR J0740+6620
Master Colloquium
Rishi Kumar
ORATED
MPIfR
Pulsar timing is a powerful tool in modern astrophysics, enabling high
precision investigations of fundamental physics. Accurate timing
measurements of neutron stars enable precise pulsar mass determination,
stringent tests of general relativity, constraints on the equation of
state of dense matter, and, through pulsar timing arrays (PTAs), a
pathway to detecting low-frequency gravitational waves from
supermassive black hole mergers.
However, the presence of radio frequency interference (RFI) continues to
limit the precision of such measurements. In an increasingly crowded
radio environment and with telescopes operating across wider
bandwidths, traditional statistical thresholding methods for RFI
excision often prove inadequate. Therefore, a machine learning based
approach is essential to handle the complexity of modern RFI. In this
work, we develop a neural network–based technique for RFI flagging in
averaged pulsar data and evaluate its performance against conventional
statistics-based methods implemented in the pulsar analysis software
PSRCHIVE. We then perform narrow-band and wide-band timing analysis of
the millisecond pulsar PSR J0740+6620 using data processed through both
RFI mitigation strategies, and we derive the mass of
the pulsar to be $2.140\pm0.030 M_{\odot}$, consistent with
previously published values within $1\sigma$. This study demonstrates
the potential of neural networks in enhancing the robustness of pulsar
timing pipelines, particularly in preparation for next-generation radio
observatories.
Magnetic fields in the multiphase interstellar medium of the Milky Way
Main Colloquium
Dr. Amit Seta
ORATED
ARC DECRA fellow at the Australian National University
Even though the interstellar medium (ISM) of star-forming galaxies has
been known to have a multiphase structure (broadly hot, warm, and cold
phases) since the 1970s, how magnetic fields differ between the ISM
phases is still unknown. Using a combination of theory, simulations,
and observations, this talk explores how the multiphase nature of the
ISM shapes magnetic fields. In particular, using Zeeman magnetic field
measurements and pulsar observations, the relationship between the
turbulent kinetic and magnetic energy densities will be established.
The findings from these studies will enhance our understanding of the
role of magnetic fields in star formation and galaxy evolution, and also
prepare us to harness the upcoming wealth of radio polarisation data
from the SKA.
The Present and Future of Millisecond Pulsar Astrometry
Special Colloquium
Dr. Hao Ding
ORATED
Mizusawa VLBI Observatory, NAOJ, Japan
With spin periods of as short as a few milliseconds, millisecond pulsars (MSPs) have been extensively observed for testing gravitational theories and directly detecting the stochastic gravitational-wave background. While most properties of MSPs are constrained with the pulsar timing technique that times and models of the pulse arrivals, the astrometric parameters of MSPs (especially the parallaxes) can be more precisely determined in the image domain with very long baseline interferometry (VLBI) in a time-efficient manner. Precise astrometric determinations for MSPs in binary/trinary systems are known to be essential for sharpening tests on gravitational theories. In this talk, I will highlight three emerging scientific prospects of MSP astrometry, including 1) probing the MSP formation channels, 2) sharpening the localizing capability of pulsar timing arrays, and 3) connecting the reference systems used by VLBI and pulsar timing. I will introduce the latest status of VLBI astrometry of MSPs with a special focus on innovative observing/data-reduction techniques, and discuss the future of precision low-frequency astrometry.
Blazar Multiwavelength Variability and the VLBI Connection
Special Colloquium
Dr. Víctor Manuel Patiño Álvarez
ORATED
INAOE-MPIfR Max Planck Partner Group Leader, Instituto Nacional de Astrofísica, Óptica y Electrónica (INAOE), México
I present some of the results obtained during the last few years by
myself and the INAOE AGN Group / Max Planck Partner Group, including the
work of the Master and PhD students. Regarding the multiwavelength
variability studies. We find that sources like 3C 279 and 3C 454.3 have
activity periods in which the gamma-rays can be dominated by either
synchrotron self-Compton (which was previously though not possible for
this type of blazars), or external inverse Compton. In the sources 3C
279, 3C 454.3, CTA 102, and B2 1633+382 we discovered the location of at
least one gamma-ray emission region within the jet, at 42 pc, 9 pc, 25
pc and 41 pc, respectively, from the central engine. For 3C 279 and 3C
454.3 we find evidence of there being multiple gamma-ray emission
regions, and in the case of the former, we can even pinpoint one of them
to a moving VLBI component. We also found evidence of the existence of
broad line emitting material that is being ionized by the jet in the
sources 3C 454.3 and CTA 102; this has important implications on the
calculation of black hole masses. Also, preliminary results from our
research show that over half of the blazar population presents this
additional broad line region.
Tuning into Star Formation: How Wideband Radio is Changing the Game
Main Colloquium
Prof. Jan Forbrich
ORATED
University of Hertfordshire
What do young stars in Orion and giant molecular clouds in Andromeda
have in common? They are now both revealed in unprecedented detail
thanks to the transformative power of wideband upgrades to radio
interferometry. Starting with the VLA and VLBA upgrades and the advent
of ALMA, radio astronomy has entered a new era - soon to be propelled
even further by the SKA and ngVLA, and initiatives like ALMA2040.
A key driver of this progress is the development of wideband radio
receivers, dramatically enhancing continuum sensitivity and enabling
simultaneous spectral line observations. In this talk, I will showcase
two examples of how these advances are reshaping star formation
science.
First, focusing on nearby star formation, I will present the Orion Radio
All-Stars, illustrating how the upgraded VLA, VLBA, and ALMA are
revolutionizing our view of young radio stars in the Orion Nebula
Cluster - the closest region of high-mass star formation. For the first
time, we have detailed information on radio emission mechanisms and
variability across a large sample of young stellar objects. These
observations provide critical new constraints on high-energy irradiation
in protostellar environments, with implications for planet formation.
Switching to nearby galaxies, I will highlight the SMA Andromeda Dust
and Molecular Gas Survey (SMA ADAMS), leveraging the wideband upgrade of
the Submillimeter Array to observe the Andromeda Galaxy - the nearest
large spiral galaxy. Dust continuum observations are essential for
characterizing molecular clouds, and for the first time, we can now
detect thermal dust emission from resolved individual Giant Molecular
Clouds in Andromeda - alongside their CO isotopologue emission. These
results are helping to bridge the gap between Galactic and extragalactic
star formation studies, placing our detailed view of local Galactic star
formation in a wider context.
Data Processing in the ngVLA era
Special Colloquium
Dr. Hendrik Müller
ORATED
National Radio Astronomy Observatory, Socorro NM, USA
Next-generation radio interferometers like ngVLA will operate at much
higher data rates and sensitivities challenging current interferometric
data processing pipelines. Scalability to the Petaflops regime per
second may be necessary. These developments are supported by the
ongoing
push towards science ready data products (SRDP), calling for high
performance, and automatized batch processing of huge data sets. NRAO
is
actively preparing for this era of big-data processing and is laying
out
the algorithmic and pipeline-heuristical foundations already now. In
this talk, I will review recent approaches to data processing by NRAO
to scale algorithms towards its next generation of flagship
instruments.
These include a novel software infrastructure envisioned to replace
CASA, especially developed for scalable deployment on GPUs.
Calibration, and particularly RFI flagging, is expected to supersede
the deconvolution as the limiting factor for the images dynamic range
and
needs to be performed iteratively with the imaging deploying the same
GPU architecture. Imaging-wise, while imaging with CLEAN was the to-go
method for decades, in view of increased sensitivity and dynamic range,
the assumption inherent to CLEAN saturate the performance unacceptably.
The development of efficient, scalable and fast wide-band and
wide-field multiscale deconvolution algorithms is paramount. Much
anticipated
convergence acceleration is achieved by clustering components informed
by Bayesian heuristics, applying concepts and ideas of convex
optimization to the CLEAN framework, and the utilization of AI for
efficient compressing among the spatial and spectral domain. Finally, I
will discuss pathways to automatization of pipelines and some computing
logistics to streamline the downstream analysis.
The Electron Density Structure of the Milky Way
Main Colloquium
Dr. Stella Ocker
ORATED
Carnegie-Caltech Brinson Fellow
The time has come for a new electron density model of the Milky Way.
Galactic electron density models describe the multi-component,
multi-scale structure of the ionized interstellar medium (ISM). These
models are routinely used to predict the distances of radio sources
lacking independent distance measures, in addition to forward modeling
the dispersion and scattering of pulsars, fast radio bursts (FRBs),
active galactic nuclei, and masers. In this talk I will discuss the
developments motivating construction of a new electron density model,
and some key puzzles that face our understanding of multi-scale electron
density structure in our Galaxy. Unlike previous models, large-scale
surveys of the ionized ISM are being actively folded into the model
construction. Specific case studies will be discussed to demonstrate how
characterization of the Galactic electron density affects our
understanding of extragalactic FRBs and their use as cosmic probes.
Unveiling the Jet and Magnetic Field Dynamics of the Best Sub-Parsec Binary Black Hole Candidate OJ 287 with Space VLBI
Special Colloquium
Dr. Efthalia Traianou
ORATED
Instituto de Astrofísica de Andalucía-CSIC, Granada
OJ 287 is one of the most fascinating blazars, believed to host a
binary supermassive black hole system and known for its rich history of
multi-wavelength variability. In this talk, I will present
high-resolution 22 GHz space VLBI observations of OJ 287 from
RadioAstron (April 2016), offering a unique view of its jet structure
and magnetic field topology at sub-milliarcsecond scales. Our imaging
reveals a bent jet morphology, significantly more extended than seen in
previous years. Using regularized maximum-likelihood imaging and
polarimetric analysis, we observe a transition in the magnetic field
from a toroidal-dominated core to a helical structure downstream,
indicating an evolving jet. Additionally, model-fitting suggests the
emergence of a new component, likely linked to the December 2015
optical outburst and the secondary black hole's passage through the
primary's accretion disk.
Unfortunately, this talk had to be cancelled.
Special Colloquium
Dr. Shafqat Riaz
ORATED
University of Tuebingen
Cancelled -- Cancelled -- Cancelled
Coupled chemical-dynamical simulations of hot cores and hot corinos
SFB Colloquium
Prof. Robin Garrod
ORATED
University of Virginia
The interstellar medium provides an enormous laboratory for the
exploration of chemistry of various kinds. Some of the most
molecule-rich interstellar objects - known as "hot molecular cores" -
are accretions of warm gas and dust that surround young protostars,
which ultimately evolve into high-mass stellar systems. Along with
their low-mass (solar-type) analogs, "hot corinos", they are
characterized by rich rotational emission spectra that exhibit a
wealth of organic molecules of varying degrees of complexity. But the
formation of these "hot" (>100 K), gas-phase molecules is closely
related to an earlier stage of chemistry that occurs on the surfaces
of microscopic dust grains at much lower temperatures. Recent
observational, experimental and modeling evidence indicates that some
of the most complex molecules that we detect in highly evolved
protostellar systems may have a much earlier origin than previously
thought.
Here I will present new modeling treatments that allow us to trace the
continuum of hot and cold chemistry involving interstellar organics. I
will also demonstrate some initial results from new coupled radiation
hydrodynamics and gas-grain chemical modeling of hot core/corino
systems, and our efforts to simulate observations of their molecular
line emission.
Origin and Fate of Cool Gas in and around Galaxy Clusters
Special Colloquium
Dr. Eric Rohr
ORATED
Max Planck Institute for Astronomy, Heidelberg
The intracluster medium (ICM) today is comprised largely of hot, X-ray
emitting gas at approximately the virial temperature of the cluster,
where smaller cool gas clouds of unknown origin and lifespan are
scattered throughout it. Using the collection of 352 cosmological
zoom-in magneto-hydrodynamic simulations of massive clusters
(M_200c(z=0) ~ 10^14.3-15.4 M_sun) in the TNG-Cluster simulation, which
employs the highly successful TNG galaxy formation model, I quantify
the evolution of the cool (T ~ 10^4-4.5 K) ICM across cluster-centric
distance, gravitational origin, and cosmic epoch, where the cluster
progenitors unambiguously had more cool halo gas than their
descendants.
Importantly, I demonstrate that in TNG-Cluster, a majority of the cool
cluster gas today is found in satellite galaxies and the cluster
centers for cool-core clusters. Moreover, the kinetic mode of SMBH
feedback, which is primarily responsible for quenching massive galaxies
in the
TNG simulations, drives the evolution of the thermodynamic properties
of the "smooth" (i.e., gas not bound to satellite galaxies)
multiphase
ICM out to $\sim$Mpc scales. As the multiphase ICM depends on the
implemented baryonic physics and feedback, comparisons across models
and with observations can be used to guide the next generation of
cosmological simulations, and I make the first such comparison here
using recent eBOSS and DESI observations of MgII absorption features in
background quasars.
Studies of the Envelopes of Evolved Stars using Millimetre and Submillimetre Spectroscopy
Promotionskolloquium
Manali Jeste
ORATED
Max-Planck-Institut für Radioastronomie
Asymptotic giant branch (AGB) stars are low- to intermediate-mass stars
at the end of their life. At this stage of the stellar evolution, these
objects shed large amounts of matter in the form of gas and dust,
forming a circumstellar envelope around them and enriching the
interstellar medium. In this talk, I will present my thesis work where
we probe these envelopes using carbon-bearing species, the C atom, and
various molecules, with observations from different single-dish
telescopes. We use the rotational lines of the HCN molecule, arising
from its ground and vibrationally excited states, to study the inner
and hotter parts of the envelope, whereas fine-structure lines of
atomic and ionised carbon (C 0 and C + ) are used to constrain their
distribution in the envelope of the archetypal star, IRC +10216.
Furthermore, we focus on AGB stars as a population and analyse 445
stars
as part of the Nearby Evolved Stars Survey (NESS) collaboration.
We observed transitions of the CO molecule from multiple rotational
states to derive their physical parameters along with mass-loss rates. I
will
explore the statistical distributions of the inferred stellar
parameters
and demonstrate how the statistical analysis of a stellar population
confirms and extends our understanding of its contribution to the
cosmic cycle of matter.
Galaxy Evolution Meets Large Scale Structure
Main Colloquium
Dr. Reza Ayromlou
ORATED
University of Bonn
In this talk, I will present an overview of my research into the
interplay between galaxy evolution and large-scale structure. I'll
delve into the effects of both intrinsic physical processes, such as
Supernova and AGN feedback, and external environmental effects on the
evolution of galaxies and gas, with a focus on large-scales. This
includes theoretical studies based on simulations like L-Galaxies,
IllustrisTNG, EAGLE, and SIMBA, alongside observational data from SDSS,
DESI, and XMM-Newton, among others. A central aspect will be
understanding how feedback processes not only regulate star formation
within galaxies but also drive the redistribution of gas within and
beyond dark matter halos, reaching a newly identified characteristic
scale called the Closure Radius. Additionally, I will explore how
environmental processes influence galaxy and gas properties across
various spatial scales. Finally, I will discuss how the interplay
between intrinsic and external processes can induce correlations in
galaxy properties from kiloparsec (kpc) to several megaparsec (Mpc)
scales, significantly exceeding the virial radii of even the largest
galaxy clusters—a phenomenon known as galactic conformity. Finally, I
highlight critical pathways for future theoretical and observational
studies aimed at unraveling the physical of galaxy formation and
evolution across different scales.
The BOAT that rocked: the multi-wavelength picture of GRB 221009A
Main Colloquium
Dr. Lauren Rhodes
ORATED
McGill
The deaths of massive stars are sometimes accompanied by the launch of
highly relativistic and collimated jets identified as gamma-ray bursts
(GRBs). GRB 221009A has been dubbed the BOAT or brightest of all time
for its record-breaking gamma-ray brightness. In this talk, I will
present a summary of the observations conducted by my collaborators and
I (Bright & Rhodes et al 2023, Fulton et al 2023, Rhodes et al 2024),
resulting in comprehensive multi-wavelength coverage including the most
detailed radio study of any GRB to date. At radio frequencies, it is
also the brightest radio counterpart detected to date and our campaign
spanned over three orders of magnitude in frequency space starting a few
hours post burst and continuing to this day (over 900 days later). I
will discuss the importance of such coverage for theoretical modelling
and our understanding of jet geometry for all manner of jetted
transients from tidal disruption events to x-ray binaries. Finally, I
will present a brief overview of our plans to continue monitoring this
fascinating object.
Prospects of higher-order statistics in the era of next-generation galaxy surveys
Promotionskolloquium
Davit Alkhanishvili
ORATED
AIfA, Bonn
The Lambda-CDM model is the standard in cosmology, with large-scale
structure clustering measurements playing a key role in parameter
constraints. Next-generation galaxy surveys highlight the growing
importance of higher-order statistics like the bispectrum, which offers
improved constraints but introduces computational challenges. This
thesis focuses on modeling the bispectrum using perturbation theory to
enhance its role in extracting cosmological information. First, we test
next-to-leading order perturbation theory expansions using N-body
simulations, finding that effective field theory (EFT) provides the most
accurate small-scale predictions. We also assess the impact of
systematic and statistical errors. Next, we demonstrate how deep neural
networks can be employed to model survey geometry effects on the power
spectrum and bispectrum, achieving high accuracy with efficient
computation. Lastly, we evaluate a third-order galaxy bias expansion
against synthetic Eucilid-like survey catalogues, demonstrating that
combining the power spectrum and bispectrum allows accurate cosmological
parameter extraction up to mildly non-linear scales, improving
constraints by a factor of 2-5 over the power spectrum alone.
Bridging Plasma Scales: Micro-to-Macro Coupling in Cosmic-Ray Propagation and Its Implications for Cluster Radio Morphologies
Main Colloquium
Patrick Reichherzer
ORATED
University of Oxford
Galaxy clusters host a zoo of radio morphologies—from compact bubbles and extended halos to sausages, bridges, and relics—all generated by cosmic rays (CRs) interacting with magnetic fields. The transport of these CRs across galaxy clusters reflects a reciprocal interaction across plasma scales. Large-scale processes (≳kpc) typically influence microscale behavior (~npc), but we show that microscale fluctuations—inherently patchy and intermittent in nature—shape large-scale radio morphologies in galaxy clusters by mediating CR propagation. This patchiness creates a heterogeneous medium where various plasma microinstabilities collectively affect CR transport. Our multi-scale simulations (kinetic to MHD) show a scale-dependent diffusion coefficient, with a transition at ~1–10 kpc: diffusion dominates below this scale, while advection takes over above it. This interplay shapes radio morphologies, revealing that microscale physics significantly affects macroscopic CR transport. We reveal that microscale physics isn't just driven—it actively sculpts the radio sky, offering testable predictions for next-generation observations.
Limb-brightened jets from anisotropic nonthermal electrons
Special Colloquium
Dr. Yuh Tsunetoe
ORATED
Harvard University
Very long baseline interferometry (VLBI) observations reveal that
relativistic jets like the one in M87 have a limb-brightened,
double-edged structure. Meanwhile, analytic and numerical models
struggle to reproduce this limb-brightening. We propose a model in
which we invoke anisotropy in the distribution function of
synchrotron-emitting nonthermal electrons such that electron velocities
are preferentially directed parallel to magnetic field lines, as
suggested by recent particle-in-cell simulations. We implement our
emission model in both general relativistic magnetohydrodynamic (GRMHD)
simulations and axisymmetric force-free electrodynamic (GRFFE) jet
models and produce simulated jet images at multiple scales and
frequencies using polarized general relativistic radiative transfer. We
find that the synchrotron emission is concentrated parallel to the local
helical magnetic field and that this feature produces limb-brightened
jet images on scales ranging from tens of microarcseconds to hundreds of
milliarcseconds in M87. We also present theoretical predictions for
horizon-scale images that can be tested with next generationinstruments.
Due to the scale-invariance of the GRMHD and GRFFE models, our emission
prescription can be applied to other targets and serve as a foundation
for a unified description of limb-brightened images of extragalactic
jets.
Exploring Radio Point Sources in the Galactic Center using the MeerKAT Radio Telescope
Master Colloquium
Kamalpreet Kaur
ORATED
MPIfR/Bonn
Recent radio observations of the Galactic Center (GC) have revealed a
significant population of point sources, including potential pulsars and
other compact objects. Detecting pulsars in the GC is challenging due to
scattering effects that smear pulsed signals. However, image-based
search techniques can overcome this limitation and identify potential
pulsar candidates. Additionally, under certain conditions, the
supermassive black hole Sagittarius A* (Sgr A*) can also be treated as a
point source. It exhibits variability across the electromagnetic
spectrum, with short-time variability at low radio frequencies (< 3 GHz)
still largely unexplored. This work has two main objectives. Firstly,
we identify potential pulsar candidates using the S4 band (2.62-3.50
GHz) of the MeerKAT Radio Telescope. We discovered 13 new unresolved
sources by applying image-based techniques and proposed three potential
pulsar candidates based on their spectral index. This highlights the
importance of image-based search in identifying potential pulsar
candidates in the scattering-dominated GC. Secondly, from the
observation conducted on 21st March 2024, we report on the flux
variability of Sgr A* with a modulation index of 5.38% at 2.79 GHz. This
is done for the first time using the MeerKAT Radio Telescope, offering
access to previously uncharted parameter space, which will help better
understand variability and emission processes in Sgr A*.
XRISM's High-Resolution X-ray Spectroscopy: Early Results on Galaxy Cluster Dynamics
Main Colloquium
Prof. Naomi Ota
ORATED
Nara Women’s University
The XRISM satellite, launched in 2023, is the successor to Hitomi and
marks a major step forward in high-resolution X-ray spectroscopy.
Equipped with the microcalorimeter spectrometer Resolve, XRISM enables
precise measurements of gas motions and turbulence in galaxy clusters.
In this talk, I will present the initial results from XRISM
observations
of the A2029 galaxy cluster, highlighting gas dynamics in the cluster
core and the role of non-thermal pressure in the outer regions. I will
also discuss future prospects, including upcoming observational
strategies and implications for galaxy cluster studies.
Mapping the Cosmic-Ray Ionization Rate in the Solar Neighborhood
SFB Colloquium
Dr. Nick Indriolo
ORATED
Johns Hopkins University, Baltimore
Chemical complexity in the molecular interstellar medium (ISM) is driven by fast ion-molecule reactions. This network of chemical reactions requires a source of ionization, and as molecular gas is generally well-shielded from ionizing UV photons, cosmic rays provide the dominant source of ionization in such environments. The impact of cosmic rays on atomic and molecular hydrogen is parameterized as the cosmic-ray ionization rate (CRIR; number of ionizations per atom/molecule per unit time), which serves as an important input variable in astrochemical modeling. Our understanding of cosmic rays in both diffuse and dense gas has vastly improved over the past decade as more detailed chemical models have been developed, and as more sensitive observations of molecules that respond to the CRIR have been made. The recent creation of 3D dust maps using Gaia differential extinction measurements allows, for the first time, ionization rates inferred from observations of molecular absorption lines to be assigned to a physical location in the nearby Galaxy. By combining this information we are beginning to build the first map of the CRIR in the solar neighborhood. I will discuss our ongoing work on this project, and how we can use such a map to better understand cosmic-ray acceleration and propagation.
Charming the Cosmic Lens: Bayesian Strong Lensing in the Era of Next-Generation Radio Astronomy
Special Colloquium
Julian Ruestig
ORATED
DZA
Strong gravitational lensing, a consequence of general relativity,
magnifies distant background sources and transforms them into complex
shapes when passing behind massive foreground objects. This powerful
phenomenon offers a unique view into the distant cosmos by probing
directly the distribution of dark matter and providing independent
constraints on the Hubble constant. These research objectives call for
the utmost precision in the estimation of the distributions of the lens
mass and the source surface brightness. Fortunately, we stand at the
threshold of a new era - recent and future strides in radio telescope
technology, such as SKA and DSA 2000, promise to provide an abundance
of observations of unprecedented quality. Realizing the full potential
of these advancements hinges on achieving the highest reconstruction
fidelity. In this talk, I will introduce LensCharm, a novel Bayesian
approach for strong-lensing signal reconstruction that can be connected
to Bayesian imaging algorithms such as resolve, allowing for
non-parametric reconstruction of both source brightness and lens mass
distribution along with their uncertainties.
Science impact by improving the eyesight of an All Southern Sky Survey
Master Colloquium
Lynn Hansen
ORATED
MPIfR/AIfA
The SKAMPI telescope is a new 15-m single-dish prototype telescope
operated by the MPG as a stand-alone observatory and is currently
undergoing system performance and science verification analyses. It is
located on the South African SKA-mid site and equipped with an S-band
and a Ku-band receiver.
Utilizing SKAMPI, an S-band All Southern Sky Survey in total intensity
covering 1.75-3.5GHz has been performed, which serves as a pathfinder to
explore observation strategies for upcoming all sky surveys. This work
presents an evaluation of SKAMPI's antenna pointing model, which
accounts for systematic effects due to collimation errors, encoder
offset, nonorthogonality of axes, axis plane tilt, and possible
gravitational effects acting on the telescope dish. Additionally, a
first version of the Ku-band pointing model has been estimated. The
impact of the individual model parameters is tested and an optimised
pointing model reducing the number of model parameters from 9 to 5 is
proposed, thereby minimizing systematic pointing effects that would
propagate into future surveys. A power spectrum analysis has been used
to investigate the impact on the overall structure of the Galactic
foreground and its scientific impact on CMB studies. We find that the
change in the pointing model impacts various angular scales and can be
associated with the primary beam properties of the telescope.
Deuterated Ammonia in High-mass Star-forming Clumps
Master Colloquium
Survi Kumari
ORATED
MPIfR/AIfA
Massive stars (≥8M⊙) are essential for the evolution of galaxies as
they influence the surrounding medium and the subsequent star formation
activity. They are much rarer than their lower-mass counterparts and
are
known to be formed in dense molecular clumps. Moreover, high-mass star
forming clumps
evolve on shorter timescales, within dynamic and complex environments
and are still deeply embedded in their parent molecular cloud during
the
earliest phases, making it difficult to study the initial conditions
involved. This makes the study of high-mass star forming regions
extremely important and challenging. In these early stages, the gas
temperature is low, allowing the environments to be probed by molecules
whose rotational lines lie in the sub-millimeter wavelength range.
Ammonia is a key tracer of dense gas and in dense, pre-stellar cores,
reactions with deuterated ions (such as H2D+) convert it into its
deuterated isotopologues NH2D, NHD2, and ND3. The abundance of
deuterium
bound in molecules (with respect to its parent species) is orders of
magnitude higher in cold molecular clouds than the primordial [D]/[H]
ratio (∼ 10e−5, Oliveira et al. 2003). The variation in deuterium
fractionation has been used as a tracer of the evolutionary phases in
low-mass star formation, therefore in my master’s thesis I
investigate
if the same can be done for the high-mass regime.
Full-polarization variability of Sgr A* from ALMA
Special Colloquium
Mr. Ezequiel Albentosa-Ruiz
ORATED
Universitat de València, Spain
The Galactic Center supermassive black hole, Sagittarius A* (Sgr A*),
provides a unique laboratory for studying astrophysical variability
across wavelengths. Using high-cadence, full-polarization light curves
from ALMA observations during the 2018 Event Horizon Telescope (EHT)
campaign (April 21–25), we analyze Sgr A*'s variability and
polarization properties with standard time-series analysis tools.
Comparing these results with the April 2017 light curves offers insights
into the variability and consistency of Sgr A*'s behavior across both
observational campaigns.
We also take a closer look at April 24, 2018, when Chandra detected a
notable X-ray flare, to investigate the time delay between high-energy
and mm-wavelength peaks. Finally, we compare the observed variability in
our light curves with predictions from GRMHD simulations, evaluating
accretion models near Sgr A* under extreme conditions. The results
presented in this talk provide new insights into Sgr A*'s accretion
dynamics and multi-wavelength emission.
An observational study of the active repeating FRB, FRB 20240114A, using the Effelsberg 100-m Radio Telescop
Master Colloquium
Pranav Limaye
ORATED
AIfA/MPIfR
Fast Radio Bursts (FRBs) are extremely bright, coherent, short-duration
flashes of radio light with an extragalactic origin. While some FRBs
are
known to repeat, a significant fraction have only been detected as
one-off events. The underlying progenitor responsible for these
intense,
extragalactic radio bursts remains an open question. Although the
coherent emission from these objects is observed over a very narrow
bandwidth, different bursts from the same source can span a broad range
of frequencies, making detection challenging for radio telescopes with
limited bandwidth.
This work presents an observational study of the active repeating FRB,
FRB 20240114A, using the Effelsberg 100-m Radio Telescope. The newly
installed Ultra BroadBand receiver on the telescope enables the study
of
FRBs over a wide frequency range of 1.3–6 GHz. Conducting FRB
observations with this receiver allowed for the collection of a rich
broadband sample of bursts from FRB 20240114A. Various statistical
analyses were performed on this sample, comparing results with existing
FRB studies and exploring potential connections to neutron stars, which
are among the most widely favored FRB progenitor models.
Revealing EMRI/IMRI candidates by QuasiPeriodic ultrafast Outflows - QPOuts
Main Colloquium
Dr. Michal Zajaček
ORATED
Department of Theoretical physics and Astrophysics, Faculty of Science, Masaryk University, Brno, Czech Republic
I will describe the detection of quasiperiodic ultrafast outflow in the
system ASASSN-20qc at z=0.056 (Pasham et al., 2024). The outflow is
revealed in the X-ray spectra as an absorption feature, which is
periodically enhanced every ~8.5 days. The periodic nature of the
ultrafast outflow is best explained by an orbiting perturber that is
inclined with respect to the accretion flow. In this way, the orbiting
body pushes the disc gas into the outflow funnel, where it is then
accelerated by the ordered magnetic field (Sukova et al. 2021). The
observed period of 8.5 days, in combination with the inferred SMBH mass
of 10^7-10^8 Msun, indicates a semi-major axis of ~100 gravitational
radii. The observed outflow rate to inflow rate ratio puts constraints
on the influence radius of the perturber. For ASASSN-20qc, the influence
radius of 3 gravitational radii suggests the presence of a massive
perturber in the intermediate-mass black hole (IMBH) mass range.
Quasiperiodic ultrafast outflows (QPOuts) are thus a novel phenomenon
that can reveal new EMRI/IMRI candidates that otherwise do not exhibit
significant periodic changes in the continuum flux density (or the
accretion rate).
Long-term monitoring of the TeV-emitting binary star LS I +61°303 at multiple wavelengths
Special Colloquium
Dr. Frederic Jaron
ORATED
TU Vienna
Long-term flux monitoring of astrophysical sources enables detailed
analysis of the timing characteristics of their emission. This can be a
powerful tool to investigate the physical processes at work in these
systems. The TeV-emitting binary star LS I +61°303 has been observed
in
radio monitoring programs since 1977. It has also been the target for
monitoring at higher energies and is included in the search for
neutrinos. Periodic signals in the radio emission from this source have
been observed to be present and remain stable over decades. Modulation
patterns are systematically related across the electromagnetic
spectrum.
I will discuss these findings in a scenario of periodic accretion onto
a
compact object and different emission regions within a precessing jet.
TBD
Special Colloquium
Dr. Paola Domínguez Fernández
CANCELED
Center for Astrophysics | Harvard & Smithsonian
TBD
Cosmic Duets: Decoding Gravitational Waves with Dual AGN
Special Colloquium
Dr. Martina Scialpi
ORATED
INAF
A large population of AGN pairs residing in the same galaxy—the
so-called dual AGN—is predicted to exist at redshifts z > 0.5. These
systems constitute the parent population of merging black holes (BHs),
making their number and properties a key starting point for theoretical
predictions on the level of the gravitational wave (GW) background and
the event rate investigated in pulsar timing array (PTA) experiments and
by the future LISA mission.
Until recently, only a handful of dual AGN had been identified at
sub-arcsec separations. In this talk, I will present the first
statistically significant sample of these systems with separations
ranging from 0.15" to 0.8" (~ kpc at z>0.5), selected using the
innovative Gaia multi-peak (GMP) technique.
However, follow-up observations are needed to confirm the nature of
these objects and distinguish true dual AGN from gravitationally lensed
systems. I will showcase spatially resolved optical and near-IR
spectroscopy data of approximately 50 systems at cosmic noon, obtained
with ground-based AO-assisted instruments including Keck, VLT, and LBT.
Additionally, I will present how combining low-frequency and VLBI radio
data with optical/IR observations enables us to confirm
optically-selected objects and identify strong radio-selected dual
AGN/lens candidates.
Building on the classification of these systems, I will also present the
first study of dual AGN properties, including the luminosity and the
mass functions, their separation distributions, their fraction within
the total AGN population, and how these characteristics evolve with
redshift.
A New Era of Precision SMBH Mass Measurements with GRAVITY+
Main Colloquium
Dr. Taro Shimizu
ORATED
MPE
Near-infrared interferometry is a unique tool to study the inner
sub-parsec structure of AGN which is inaccessible with current single
dish telescopes. With VLTI/GRAVITY, we can now spatially resolve not
just the hot dust continuum on milliarcsecond scales through imaging but
also the broad-line region on microarcsecond scales through
spectro-astrometry. In this talk, I will review the latest results from
our observations of local AGN with GRAVITY where we have mapped the
kinematics of the BLR in seven nearby AGN, measured sizes of the hot
dust for sixteen AGN, and reconstructed images for two AGN. BLR
kinematics have allowed us to independently measure the BLR size and
supermassive black hole mass where we begin to find a departure from the
radius-luminosity relation at high luminosity. I will give an overview
of the GRAVITY+ upgrades that will allow for direct black hole mass
measurements out to high redshift and therefore a precise tracing of
supermassive black hole-galaxy coevolution through cosmic time. With the
addition of wide-angle off-axis fringe tracking and a state-of-the-art
AO system, we have already pushed observations out to cosmic noon and
beyond and I will show the first results and sample from this program.
Working with SKAMPI archive metadata
Master Colloquium
Jannick Schulze
ORATED
MPIfR
The SKAMPI telescope is a new single-dish prototype telescope, located
on the South African SKA-mid site, which is currently undergoing
science commissioning. The telescope stores metadata on the state of
the telescope and environmental conditions for each observation. This
metadata can be used to investigate potential systematic errors by
studying telescope behaviour under changing conditions over time. A
workflow has been developed to validate and characterise sensor data,
using two different types of Machine Learning approaches that generate
models fully describing SKAMPI. These models have been evaluated and
learned relations have been extracted from the trained models to
validate results and investigate dependencies. A difference in azimuth-
and elevation-dependency of exceeding ADC-input saturation of the
receiver system is shown. Overall the developed workflow provides first
insights into the systematics of SKAMPI and, over a longer time span of
operation, could be used to investigate time-dependencies of said
relations. In addition it is shown that an ISS downlink emitter, or
similar satellite-based emitters, can be successfully used to image
SKAMPIs antenna pattern up to the 4th sidelobe.
Illuminating planet formation, the role of external UV radiation in the chemistry of protoplanetary disks: new results from JWST and ALMA
Main Colloquium
Dr. Javier R. Goicoechea
ORATED
IFF-CSIC
The earliest stages of (exo)planet formation takes place in
protoplanetary disks of gas and dust around young stars. It has become
evident that the majority of these disks originate within a cluster of
stars, subjecting them to intense ultraviolet (UV) radiation. Despite
its relevance to planet formation theories (our proto-Solar System disk
formed in a cluster) little is known about the role of this external UV
radiation in the formation, evolution, and chemical composition of
embryonic planetary systems. The unprecedented capabilities of JWST
combined to ground based observatories such as ALMA now enables us to
characterize protoplanetary disks irradiated by UV from the cluster.
Recent results on massive black holes in the first few billion years
Main Colloquium
Dr. Hannah Uebler
ORATED
MPE
One of the most surprising results coming out of the first two years of
science operations with JWST is the unexpectedly high abundance of
actively accreting black holes in the early Universe. Compared to the
local population, many of these early black holes appear to differ in
various aspects, such as their relation to their host galaxies or their
multi-wavelength properties. These observational findings challenge our
understanding of the past evolution of present-day supermassive black
holes, and provide new ways to constrain theoretical models of black
hole formation and growth. I will give an overview of recent
observational results on massive black holes in the first few billion
years and how they fit into current models, largely driven by the
unprecedented capabilities of JWST to explore cosmic dawn, and with a
focus on results from the NIRSpec GTO surveys JADES and GA-NIFS.
Recent Advances in AGN Jet Research by the Global VLBI Alliance
Special Colloquium
Prof. Dr. Jongho Park
ORATED
KyungHee University
Very Long Baseline Interferometry (VLBI) achieves ultrahigh angular
resolution by utilizing widely separated radio telescopes. The quality
of VLBI images improves with more participating telescopes, a principle
realized by the Global VLBI Alliance (GVA). In this talk, I will present
recent advances in AGN jet studies enabled by the GVA.
1. We identified a dense, cold ambient medium near the core of the 3C 84
jet, which guides its propagation on parsec scales and significantly
influences its overall shape.
2. Our observations of NGC 315 reveal that its jet, previously known for
a center-brightened morphology at parsec scales, is actually
edge-brightened—a feature unresolved in earlier VLBI studies.
I will discuss the physical implications of these findings and explore
future research opportunities with the GVA and the Global Millimeter
VLBI Array (GMVA).
Modern Astronomical Observations provide high-fidelity images that might
contain complex structures. The effective approaches to analyzing these
structures remain missing. Here, I present a method, which can extract
information from these maps by analyzing the relationship between
measurement values from adjacent pixels. The method can reveal
regularities in the parameter space, which is hard to obtain otherwise,
and can provide optimal ways to divide a region into patches of
heterogeneous properties. I provide examples where the method has been
used to analyze astronomical, medical, agricultural, and climate images.
Active Galactic Nuclei as Cosmic Particle Accelerators
Main Colloquium
Dr. Frank Rieger
ORATED
IPP
Accreting supermassive black holes are believed to drive the energy output in the form of radiation and relativistic plasma outflows (jets) seen in active galactic nuclei (AGN). As the most powerful, persistent sources in the Universe, AGN provide a unique possibility to explore the realm of extreme physics. I will highlight some recent advances in the high-energy plasma diagnostics of these objects, ranging from magnetospheric processes in the vicinity of supermassive black holes to the physical characteristics of their large-scale jets. On black-hole horizon scales, for example, gap-type particle acceleration is a likely mechanism behind the rapidly variable gamma-ray emission observed in sources such as M87, and may supply the plasma necessary for continuous jet formation. On larger scales, a combination of first and second-order Fermi-type acceleration processes presumably plays a key role in shaping the non-thermal emission properties of AGN jets. I will give an introduction to these scenarios, comment on their potential role for ultra-high energy cosmic-ray production, and address some of the key challenges currently facing this field.