RX J0420.4-5457 , the SIMBAD biblio

NGC 1566, a southern galaxy with an exceptionally regular spiral pattern, was observed in radio continuum at λ3.5, 6.2, 12.7 and 21.7cm wavelengths with the Australia Telescope Compact Array (ATCA), and in the optical Hα line with the MSSO 1.0-m telescope. The total radio emission has a smooth nonthermal component and a thermal component associated with Hα emission. Even at λ3.5cm the thermal emission dominates only in the western spiral arm. The nonthermal intensities require an equipartition magnetic field of 13±2µG average strength, and ≃15-20µG in spiral arms. For the first time linearly polarized radio emission has been detected in NGC 1566. At λ6.2cm the highest polarized intensities with a degree of polarization p≃30% emerge from interarm regions, possibly a result of magnetic field compression between two spiral arms. No such phenomenon has been observed for any other spiral galaxy. As Faraday rotation is low, the (B)-vectors at λ6.2cm indicate the orientations of the magnetic field lines which almost perfectly follow the optical spiral structure. No systematic variations of the field pitch angles from spiral arm to interarm regions were found, in contrast to density-wave models. The polarized emission at λ12.7cm is 2.5-10 times lower than at λ6.2cm. If this is due to internal Faraday dispersion in the halo of NGC 1566, we would need electron densities of n_e>0.03cm^–3. We observed NGC 1566 in X-rays with the Position Sensitive Proportional Counter (PSPC) aboard the Roentgen Satellit (ROSAT). The bright nuclear region with a luminosity of L_x(0.1-2.4keV)=1.0x10⁴¹erg/s can best be fitted with a power-law spectral model of index 2.3 that is in good agreement with the mean index for Seyfert type I galaxies. Besides the nuclear source we detected point sources in the spiral arms of NGC 1566 and extended emission (L_ x_=1.4x10⁴⁰erg/s) surrounding the nucleus. The extent of the radio continuum emission is similar to that of the extended X-ray emission, suggesting a link between hot gas and magnetic field. Assuming that the extended soft X-ray emission is due to a hot gaseous component, we derive an electron density <1.0x10^–3/sqrt(η)cm^–3 with an unknown volume filling factor η. This is too small to explain the observed depolarization at λ12.7cm, indicating that the hot gas is far from radiative equilibrium, or that another component of ionized gas with lower temperature exists in the halo.