Your search keyword '"Dominici, T."' showing total 2 results

1. Particle acceleration and magnetic field structure in PKS 2155−304: optical polarimetric observations U. Barres de Almeida et al. Optical polarimetry of PKS 2155−304.

Author

De Almeida, U. Barres, Ward, M. J., Dominici, T. P., Abraham, Z., Franco, G. A. P., Daniel, M. K., Chadwick, P. M., and Boisson, C.

Subjects

MAGNETIC fields, OPTICAL measurements, PARTICLE acceleration, ELLIPSOMETRY, NUCLEAR physics

Abstract

In this paper, we present multiband optical polarimetric observations of the very-high energy blazar PKS 2155−304 made simultaneously with a HESS/ Fermi high-energy campaign in 2008, when the source was found to be in a low state. The intense daily coverage of the data set allowed us to study in detail the temporal evolution of the emission, and we found that the particle acceleration time-scales are decoupled from the changes in the polarimetric properties of the source. We present a model in which the optical polarimetric emission originates at the polarized mm-wave core and propose an explanation for the lack of correlation between the photometric and polarimetric fluxes. The optical emission is consistent with an inhomogeneous synchrotron source in which the large-scale field is locally organized by a shock in which particle acceleration takes place. Finally, we use these optical polarimetric observations of PKS 2155−304 at a low state to propose an origin for the quiescent gamma-ray flux of the object, in an attempt to provide clues for the source of its recently established persistent TeV emission. [ABSTRACT FROM AUTHOR]

Published

2010

2. Free–free absorption in the nucleus of Cen A: evidences from 7-mm emission variability.

Author

Abraham, Z., Barres de Almeida, U., Dominici, T. P., and Caproni, A.

Subjects

CONSTELLATIONS, ACTIVE galaxies, ASTROPHYSICAL jets, ELECTRONS, METAPHYSICAL cosmology, ASTROPHYSICS

Abstract

The existence of free–free absorption in the nucleus of Cen A was suggested by Tingay & Murphy in 2001 as an explanation for the large value of the spectral index between 2.2 and 5 GHz. In this paper we present further evidence for this absorption, based on the observations of short time-scale variability at mm wavelengths and their lack of correlation with X-ray emission, as expected if they were both originated in the same physical process. To explain the short-term variability, we assumed that the mm-wave emission is produced near the base of the inhomogeneous parsec-scale jet that has a bulk velocity of about 0.5 c. The presence of an ionized media between the jet and the observer will produce the observed 7-mm flux density variability, as different jet features move behind the absorbing material. We estimated that a region with 5 × 106 electrons cm−3 and 1.5 × 1015 cm radius can explain the intensity and the duration of the mm-flux variations, but the corresponding column density would not be enough to absorb significantly the X-ray flux, explaining the lack of correlation between the radio and X-ray variability. The upper limit for the cloud size inferred for the absorbing region shows that the media surrounding the core of Cen A must be clumpy. [ABSTRACT FROM AUTHOR]

Published

2007