Litcius/Paper detail

Reverberation of pulsar wind nebulae – II. Anatomy of the ‘thin-shell’ evolution

R. Bandiera, N. Bucciantini, J. Martín, Barbara Olmi, D. F. Torres

2023Monthly Notices of the Royal Astronomical Society18 citationsDOIOpen Access PDF

Abstract

ABSTRACT During its early evolution, a pulsar wind nebula (PWN) sweeps the inner part of the supernova ejecta and forms a thin massive shell. Later on, when the shell has been reached by the reverse shock of the supernova remnant, the evolution becomes more complex, in most cases reverting the expansion into a compression: this later phase is called ‘reverberation’. Computations done so far to understand this phase have been mostly performed in the thin-shell approximation, where the evolution of the PWN radius is assimilated to that of the swept-up shell under the effect of both the inner pressure from the PWN, and the outer pressure from the supernova remnant. Despite the thin-shell approach seems rather justifiable, its implementations have so far been inaccurate, and its correctness, never tested. The outer pressure was naively assumed to be scaled according to the Sedov solution (or a constant fraction of it) along the entire evolution. The thin-shell assumption itself fails along the process, being the shell no longer thin in comparison with the size of the PWN. Here, through a combination of numerical models, dimensional arguments, and analytical approximations, we present a detailed analysis of the interaction of the PWN with the supernova remnant. We provide a new analytical approximation of the outer pressure, beyond the Sedov solution, and a revised ‘thin-shell’ able to reproduce results from numerical simulations. Finally, we compute the efficiency by which the PWN is compressed during reverberation over a wide population of sources.

Topics & Concepts

PhysicsEjectaSupernovaAstrophysicsShell (structure)Pulsar wind nebulaSupernova remnantRADIUSRadiation pressurePulsarReverberationPopulationDemographyMaterials scienceComputer securityComposite materialSociologyComputer scienceAcousticsPulsars and Gravitational Waves ResearchAstrophysics and Cosmic PhenomenaGamma-ray bursts and supernovae
Reverberation of pulsar wind nebulae – II. Anatomy of the ‘thin-shell’ evolution | Litcius