Mapping the core of the Tarantula Nebula with VLT-MUSE: I. Spectral and nebular content around R136

TL;DR

This study uses VLT-MUSE spectroscopy to map the stellar and nebular content of the Tarantula Nebula's core, revealing complex gas kinematics, stellar velocities, and interstellar medium properties around R136 in unprecedented detail.

Contribution

First comprehensive spectroscopic survey of the Tarantula Nebula's core, providing detailed stellar and nebular data with insights into gas dynamics and star formation regions.

Findings

Complex bi-modal gas velocity distribution around R136

Identification of point sources related to star formation or stellar phenomena

Red-shifted material near X-ray sources indicating dynamic interactions

Abstract

We introduce VLT-MUSE observations of the central 2$'\times2'$ (30$\times$30 pc) of the Tarantula Nebula in the Large Magellanic Cloud. The observations provide an unprecedented spectroscopic census of the massive stars and ionised gas in the vicinity of R136, the young, dense star cluster located in NGC 2070, at the heart of the richest star-forming region in the Local Group. Spectrophotometry and radial-velocity estimates of the nebular gas (superimposed on the stellar spectra) are provided for 2255 point sources extracted from the MUSE datacubes, and we present estimates of stellar radial velocities for 270 early-type stars (finding an average systemic velocity of 271$\pm$41 km/s). We present an extinction map constructed from the nebular Balmer lines, with electron densities and temperatures estimated from intensity ratios of the [SII], [NII], and [SIII] lines. The interstellar medium, as traced by H$\alpha$ and [NII] $\lambda$6583, provides new insights in regions where stars are probably forming. The gas kinematics are complex, but with a clear bi-modal, blue- and red-shifted distribution compared to the systemic velocity of the gas centred on R136. Interesting point-like sources are also seen in the eastern cavity, western shell, and around R136; these might be related to phenomena such as runaway stars, jets, formation of new stars, or the interaction of the gas with the population of Wolf--Rayet stars. Closer inspection of the core reveals red-shifted material surrounding the strongest X-ray sources, although we are unable to investigate the kinematics in detail as the stars are spatially unresolved in the MUSE data. Further papers in this series will discuss the detailed stellar content of NGC 2070 and its integrated stellar and nebular properties.