M1-92: Asymptotic giant branch interruption and isotopic ratio paradox. Chemistry and morpho-kinematics from improved shapemol modelling

The shaping of planetary nebulae on their evolution from asymptotic giant branch circumstellar envelopes to their final, most often axisymmetrical, form is still a process with many unknown details. The key to understanding the whole shaping process is the study of the transition objects called pre-planetary nebulae (pPNe). In this context, modelling tools must be kept to the standard of radio telescope capabilities, so we can make the most of the data they collect. In this work we first present the newest update of the and modelling tools, adding ten new molecular species to be reproduced together with other general improvements. Later, we put this new update into practice to study a pPN with a rich chemistry that can provide valuable information on its origin and shaping. We created a 3D morpho-kinematical model of the nebula in that is able to reproduce 23 line profiles from the IRAM 30m telescope and HIFI/HSO and five maps from IRAM NOEMA. The observational dataset is reproduced simultaneously under the same physical conditions, adjusting only the relative abundance of the different species. We obtained a full description of the nebula's physical and chemical properties, and we provide the total estimates for mass (0. 79 linear momentum (4. 10), and kinetic energy (6. 48 erg) as well as their detailed distribution across the nebula. We also analysed the isotopic ratios, finding robust discrepancies (values of 10 versus 30) in the g·cm·s -1 45 ratio across structures depending on their age.