Collisional Excitation in Space: Recent Advances and Future Challenges in the JWST Era

TL;DR

This paper reviews recent progress and future challenges in collisional excitation data for astrophysics, emphasizing the impact of JWST observations and the need for advanced computational methods.

Contribution

It highlights recent advances in collisional data and identifies key gaps and frontiers, especially involving heavy projectiles and ro-vibrational excitation, for future research.

Findings

JWST observations reveal gaps in collisional databases.

Recent computational methods are expanding molecular collision data.

Addressing heavy projectiles and ro-vibrational processes is crucial.

Abstract

This perspective offers a viewpoint on how the challenges of molecular scattering investigations of astrophysical interest have evolved in recent years. Computational progress has steadily expanded collisional databases and provided essential tools for modeling non-LTE astronomical regions. However, the observational leap enabled by the JWST and new observational facilities has revealed critical gaps in these databases. In this framework, two major frontiers emerge: the characterization of collisional processes involving heavy projectiles, and the treatment of ro-vibrational excitation. The significant computational effort of these investigations emphasizes the need to test and develop robust theoretical methods and approximations, capable of extending the census of collisional coefficients required for reliable astrophysical modeling. Recent developments in these directions are outlined, with particular attention to their application and their potential to broaden the coverage of molecular systems and physical environments.