Loading…

Tracing the Milky Way spiral arms with 26Al -- The role of nova systems in the 2D distribution of 26Al

Massive stars are one of the most important and investigated astrophysical production sites of \(^{26}\)Al, a short-lived radioisotope with \(\sim\) 1 Myr half-life. Its short lifetime prevents us from observing its complete chemical history, and only the \(^{26}\)Al that was recently produced by ma...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2024-07
Main Authors: Vasini, Arianna, Spitoni, Emanuele, Matteucci, Francesca, Cescutti, Gabriele, Massimo della Valle
Format: Article
Language:English
Subjects:
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Massive stars are one of the most important and investigated astrophysical production sites of \(^{26}\)Al, a short-lived radioisotope with \(\sim\) 1 Myr half-life. Its short lifetime prevents us from observing its complete chemical history, and only the \(^{26}\)Al that was recently produced by massive stars can be observed. Hence, it is considered a tracer of star formation rate (SFR). However, important contributions to \(^{26}\)Al comes from nova systems that pollute the interstellar medium with a large delay, thus partly erasing the correlation between \(^{26}\)Al and SFR. In this work we describe the 2D distribution of the mass of \(^{26}\)Al as well as that of massive stars and nova systems in the Milky Way, to investigate their relative contributions to the production of \(^{26}\)Al. We use a detailed 2D chemical evolution model where the SFR is azimuthally dependent and is required to reproduce the spiral arm pattern observed in the Milky Way. We test two different models, one where the \(^{26}\)Al comes from massive stars and novae, and one with massive stars only. We then compare the predictions to the \(\sim\) 2 M\(_{\odot}\) of \(^{26}\)Al mass observed by the surveys COMPTEL and INTEGRAL. The results show that novae do not trace SFR and, in the solar vicinity, they concentrate in its minima. The effect of novae on the map of the \(^{26}\)Al mass consists in damping the spiral pattern by a factor of five. Regarding the nucleosynthesis, we find that \(\sim\)75% of the \(^{26}\)Al is produced by novae and the \(\sim\)25% by massive stars. We conclude that novae cannot be neglected as \(^{26}\)Al producers since the observations can only be reproduced by including their contribution. Moreover, we suggest that bulge novae should eject around six times more material than the disc ones to well reproduce the observed mass of \(^{26}\)Al.
ISSN:2331-8422