Spatially resolved optical IFU spectroscopy of the inner superwind of NGC 253

TL;DR

This study uses optical IFU spectroscopy to analyze the superwind in NGC 253, revealing detailed kinematics, shock excitation, and wind collimation, advancing understanding of starburst-driven outflows.

Contribution

It provides the first detailed kinematic and emission line analysis of NGC 253's superwind using integral field spectroscopy, revealing wind structure and shock excitation.

Findings

Superwind cone has a wide (~60°) opening angle.

Deprojected outflow speeds are a few hundred km/s, increasing with height.

Optical emission lines mainly originate from shocked gas.

Abstract

[abridged] We present optical integral field unit observations (VLT/VIMOS-IFU and WIYN/SparsePak), and associated archival deep Halpha imaging (ESO 2.2m WFI), of the nearby starburst galaxy NGC253. With VIMOS we observed the nuclear region and southern superwind outflow in detail with five pointings, and with SparsePak we observed two partially overlapping regions covering the central disk and northern halo. The high signal-to-noise of the data and spectral resolution (80-90 km/s) enable us to accurately decompose the emission line profiles into multiple components. The combination of these datasets, together with information available in the literature, has allowed us to study the starburst-driven superwind in great detail. We investigate the known minor axis outflow cone, which is well-defined in the Halpha imaging and kinematics between r=280-660 pc from the nucleus. Kinematic modelling indicates a wide opening angle (~60 deg), an inclination consistent with the disk, and deprojected outflow speeds of a few 100 km/s that increase with distance above the plane. The [NII]/Halpha and [SII]/Halpha line ratio maps imply that a significant fraction of the wind optical emission lines arise from shocked gas. From the kinematics, the cone appears partially closed in at least one place, and very broad Halpha line widths (>400 km/s FWHM) suggest there is material filling the cone in some regions. Extrapolation of the cone to its apex shows it is not centred on the starburst nucleus, suggesting the wind is deflected and collimated by the dense circumnuclear material. We discuss the implications of these findings on our understanding of the origins and evolution of the superwind. The lack of an obvious connection between the inner (r<1 kpc) Halpha and X-ray bright outflow cone and the large-scale (r<10 kpc) X-ray "horns" is also discussed.