Account
First Name | Rino |
Last Name | Bandiera |
Institution | INAF – Osservatorio Astrofisico di Arcetri |
Country | Italy |
1st Abstract
Title (1st Abstract) | Synchrotron emission in the case of a partly random magnetic field, and the study of some general properties of radio shell-type supernova remnants. |
First Author | Rino Bandiera |
Affiliation | INAF – Arcetri Astrophysical Observatory, Florence, Italy |
Additional Authors | Oleh Petruk |
Presentation options | |
Session | 1. Radiation studies from gamma-rays to radio in Galactic and Extragalactic SNRs |
1st Abstract | We present an extension of the classical synchrotron emission theory, for the combination of an ordered magnetic field plus a random component. Exact analytical formulae are obtained for a power-law distribution of radiating particles. We also discuss a treatment of the internal Faraday rotation. These results are then applied to discuss some general properties of the structure of the radio emission and polarization from shell-type supernova remnants. To this purpose we have used a thin-layer approximation to model the supernova remnant shell: this approximation does not guarantee the same level of accuracy of numerical simulations, but is adequate to show at least qualitatively how the observed maps are affected by the geometry of the source. Some further considerations are presented on the more general case in which the energy distribution of the emitting particles is not a pure power law. |
2nd Abstract
Title (2nd abstract) | A (semi)-analytic view of the inner structure of Pulsar Wind Nebulae |
First Author (2nd abstract) | Rino Bandiera |
Affiliation (2nd abstract) | INAF – Arcetri Astrophysical Observatory, Florence, Italy |
Additional Authors (2nd abstract) | Barbara Olmi, Luca del Zanna, Niccolò Bucciantini, Elena Amato |
Presentation options (2nd abstract) | |
Session (2nd abstract) | 3. Pulsar winds nebulae (including Crab flares) |
2nd Abstract | When the wind of an active pulsar impacts on the surrounding medium, it forms a termination shock (TS) that feeds a relativistic and magnetized bubble, known as “Pulsar Wind Nebula”. About thirty years ago, Kennel & Coroniti investigated this scenario, but unfortunately their results failed to match the observed morphologies. That model was in principle correct, but its main drawback was the assumption of a spherical symmetry. More recently, numerical codes have been used to simulate in detail the dynamical structure of PWNe: they have shown complex morphologies, with a closer resemblance with observations. We show how Kennel & Coroniti model can be generalized to two dimensions, by solving the jump equations for an oblique TS, and then the relativistic MHD equations in the downstream regions closest to the TS. In this way we can obtain two dimensional, steady state solutions, which in the inner regions agree quite well with the numerical ones. This method is semi-analytic and computationally rather light: given the shape of the TS (in an analytic form), the spatial behaviour of the physical quantities (like velocity, pressure, magnetic field) is derived. Maps of the synchrotron emission are also obtained. A final goal is to use semi-analytic modelling, together with numerical simulations, to improve inversion techniques, aimed at deriving the pulsar-wind parameters from observations. |