|
Promotionskolloquium |
Timea Kovacs
| SCHEDULED |
MPIfR
Magnetic fields play an important role in galaxy evolution, from
processes such as gas dynamics and star formation to galactic outflows.
However, the redshift evolution of galactic-scale magnetic fields is
not
well constrained, both observations and theoretical predictions are
lacking, with only a handful of direct magnetic field strength
measurements in distant galaxies. In my talk, I will present my results
from both radio polarimetric observations and synthetic observations
made with the IllustrisTNG50 simulation. First, I will present the
analysis of broadband (1 - 8 GHz) spectro-polarimetric Very Large Array
observations of two lensing systems (B1600+434 and B0218+357). Using
these, we measured the halo magnetic field of a distant galaxy at
z=0.414 (corresponding to 4.4 Gyr ago) for the first time with a
strength of 1.2 - 1.8 uG, and found an axisymmetric disk field of 2 -
20
uG in a lensing galaxy at z=0.685 (6.3 Gyr ago), in agreement with the
magnetic field strength and structure of nearby galaxies. Then, I will
show how the observables of magnetic fields evolve over redshift using
16 500 galaxies at redshifts of 0 < z < 2 from the state-of-the-art
cosmological magneto-hydrodynamic simulation IllustrisTNG50. I explore
two methods used to obtain cosmic magnetic field strengths: deriving
the
magnetic field strength of intervening galaxies in front of polarized
background quasars and deriving the magnetic field strength of the IGM
by utilizing FRBs. In the near future, we expect the number of known
lensing systems, quasars with intervening galaxies, and polarized FRBs
to dramatically increase by tens of thousands of systems due to new
radio surveys and telescopes. The results I am presenting demonstrate
how the lensing method can be applied to different galaxies, and
predict
measuring the magnetic field strength of the IGM with a 2 rad m^-2
precision using FRBs will be possible in under 10 years.