Herschel water maps towards the vicinity of the black hole Sgr A*

Abstract

Aims: We study the spatial distribution and kinematics of water emission in a ~64 pc2 region of the Galactic Center (GC) around Sgr A*. We also analyze the water excitation to derive the physical conditions and water abundances in the CND and the `quiescent clouds'. Methods: We presented the integrated intensity maps of the ortho 110-101, and para 202-111 and 111-000 water transitions observed with the HIFI instrument on board Herschel. To study the water excitation we used ground state ortho and para H218O transitions. In our study, we also used SPIRE continuum measurements of the CND. Using a non-LTE radiative transfer code, the water line profiles and dust continuum were modeled. We also used a rotating ring model to reproduce the CND kinematics represented by the PV diagram. Results: We identify the water emission arising from the CND, the Western Streamer, and the 20 and 50 km s-1 clouds. The ortho water maps show absorption structures in the range of [-220,10] km s-1. The PV diagram shows that the 202-111 H2O emission traces the CND. We derive high XH2O of (0.1-1.3)×10-5, Vt of 14-23 km s-1 and Td of 15-45 K for the CND, and the lower X H2O of 4×10-8 and Vt of 9 km s-1 for the 20 km s-1 cloud. Collisional excitation and dust effects are responsible for the water excitation in the southwest lobe of the CND and the 20 km s-1 cloud, whereas only collisions can account for the water excitation in the northeast lobe of the CND. We propose that the water vapor in the CND is caused by grain sputtering by shocks of 10-20 km s-1, with some contribution of high temperature and cosmic-ray chemistries plus a PDR chemistry. The low X H2O derived for the 20 km s-1 cloud could be partially a consequence of the water freeze-out on grains.