Volker Heesen, Rainer Beck, Marita Krause, Ralf-Jürgen Dettmar
Magnetic fields are a good tracer for gas compression by shock waves, which
can be caused by interaction of star-formation driven outflows from individual
star formation sites as described in the chimney model. We study the magnetic
field structure in the central part of the nuclear starburst galaxy NGC 253
with spatial resolutions between 40 and 150 pc to detect any filamentary
emission associated with the nuclear outflow. New VLA observations at 3 cm with
7.5" resolution were combined with archive data at 20 and 6 cm. We find
filamentary radio continuum emission in a geometrical distribution that we
interpret as the boundary of the northwestern nuclear outflow cone. The
scaleheight of the continuum emission is 150+/-20 pc, regardless of the
observing frequency. The equipartition magnetic field strength is 46+/-10
microG for the total field and 21+/-5 microG for the regular field in the
filaments. The ordered magnetic field is aligned along the filaments, in
agreement with amplification due to compression. The perpendicular diffusion
coefficient across the filaments is kappa_perp = 1.5 x 10^28 cm^2 s^-1
E(GeV)^(0.5+/-0.7). In the SE part of the nuclear outflow cone the magnetic
field is pointing away from the disc in form of a helix, with an azimuthal
component increasing up to at least 1200 pc height, where it is about equal to
the total component. The ordered magnetic field in the disc is anisotropic
within a radius of 2.2 kpc. At larger radii, the large-scale field is regular
and of even parity. The magnetic field is able to collimate the outflow, which
can explain the observed small opening angle of ~26 degree. Due to angular
momentum conservation, the field lines are frozen into the plasma and are wound
up into a helix. Strong adiabatic losses of the cosmic-ray electrons can partly
explain why the radio luminosity of the nucleus lies below the radio-FIR
correlation.
View original:
http://arxiv.org/abs/1109.0255
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