Little time for oscillation: Fast disruption of the Radcliffe Wave by Galactic motions

Abstract

The Radcliffe wave 2020Natur.578..237A is a 2.7 kpc long, 100 pc wide-like structure in the Galactic disk with a wave-like velocity structure 2022MNRAS.517L.102L,2024arXiv240212596K. A referent Nature paper 2024arXiv240212596K treated the Wave as a solid body in the disk plane, modeled its oscillation along the vertical direction, and derived the local Galactic mass distribution from the oscillation pattern. In reality, Galactic shear can stretch gas through differential rotation, whereas gas clouds experience epicyclic motions. We simulate the 3D evolution of the local interstellar gas and find shear and encyclic motion stretches the Radcliffe wave to almost twice its current length at the timescale of 45 Myr, within which only half a cycle of the proposed vertical oscillation occurs. The simulation also reveals the formation of new filaments and filament-filament mergers. Treating the Radcliffe wave as a solid body in the Galactic disk and an oscillating structure in the vertical direction is thus an oversimplification. Our data-driven simulation reveals the 3D evolution of the local interstellar gas with several processes at play, strengthening the role of the Solar Neighborhood as a unique test ground for theories of interstellar gas evolution.

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