Detection of spiral magnetic fields in two flocculent galaxies

According Co the classical axisymmetric dynamo concept, differentially rota ting galaxies which lack organized optical spiral patterns and density wave flows should still have spiral magnetic fields with a substantial radial c omponent. To check this hypothesis we observed two flocculent spirals, NGC 3521 and NGC 5055, in the radio continuum (total power and polarization) at 10.55 GHz with a resolution of 1.'13. A search for traces of optical spira l patterns has also been made by observing them in the Her line and by filt ering their available blue images. NGC 3521 and NGC 5055 were found to possess a mean degree of magnetic field ordering similar to that in grand-design spirals. However, the polarized e mission fills the central region of NGC 5055 while a minimum of polarized i ntensity was observed in the inner disk of NGC 3521. This can be explained by a more uniform star formation distribution in the centre of NGC 3521, wh ile a higher concentration of star-forming activity in the nuclear region a nd in the rudimentary spiral "armlets" of NGC 5055 leaves broader interarm regions with unperturbed regular magnetic fields. Both galaxies possess reg ular spiral magnetic fields with a radial component amounting to 40% - 60% of the azimuthal field. The use of beam-smoothed polarization models demons trates that this result cannot be produced by limited resolution and projec tion effects. Furthermore, a large magnetic pitch angle cannot be entirely due to the influence of rudimentary spiral-like features visible in our H a lpha and enhanced optical images. Thus it appears that the dynamo process i s responsible for the radial magnetic field in flocculent galaxies. The mea sured radial magnetic field component as compared to the azimuthal one is e ven stronger than predicted by a classical turbulent dynamo which provides arguments in support for modern, non-standard dynamo concepts.