The Galactic Centre in the Far Infrared

TL;DR

This study analyzes far infrared dust emission from the Galactic Centre, revealing a complex temperature structure and significant cold dust mass, using combined Herschel, ISO, and MSX data to improve understanding of the region's dust properties.

Contribution

It provides a detailed multi-wavelength analysis of the Galactic Centre's dust emission, identifying three dust temperature components and mapping dust grain size variations for the first time.

Findings

Cold dust dominates the total dust mass (~3.2x10^4 Msun).

The FIR SED is best modeled by three greybody components at 90, 44.5, and 23 K.

The inner CND mass is estimated at ~5.0x10^4 Msun.

Abstract

We analyse the far infrared dust emission from the Galactic Centre region, including the Circumnuclear Disk (CND) and other structures, using Herschel PACS and SPIRE photometric observations. These Herschel data are complemented by unpublished observations by the Infrared Space Observatory Long Wavelength Spectrometer (ISO LWS), which used parallel mode scans to obtain photometric images of the region with a larger beam than Herschel but with a complementary wavelength coverage and more frequent sampling with ten detectors observing at ten different wavelengths in the range from 46 to 180 \mum, where the emission peaks. We also include data from the MSX at 21.3 \mum for completeness. We model the combined ISO LWS continuum plus Herschel PACS and SPIRE photometric data toward the central 2 pc in Sgr A*, a region that includes the CND. We find that the FIR spectral energy distribution is best represented by a continuum that is the sum of three greybody curves from dust at temperatures of 90, 44.5, and 23 K. We obtain temperature and molecular hydrogen column density maps of the region. We estimate the mass of the inner part of the CND to be ~5.0x10e+4 Msum, with luminosities: Lcavity ~2.2x10e+6 Lsun and Lcnd ~1.5x10e+6 Lsun in the central 2 pc radius around SgrA* . We find from the Herschel and ISO data that the cold component of the dust dominates the total dust mass, with a contribution of ~3.2x10E+4 Msun; this important cold material had escaped the notice of earlier studies that relied on shorter wavelength observations. The hotter component disagrees with some earlier estimates, but is consistent with measured gas temperatures and with models that imply shock heating or turbulent effects are at work. We find that the dust grain sizes apparently change widely across the region, perhaps in response to the temperature variations, and we map that distribution.