The GBT diffuse ionized gas survey: tracing the diffuse ionized gas around the Giant H𝖨𝖨 region W43
Files
First author draft
Date
2020-02
Authors
Luisi, Matteo
Anderson, L.D.
Liu, Bin
Balser, Dana S.
Bania, Thomas M.
Wenger, Trey V.
Haffner, L.M.
Version
First author draft
OA Version
Citation
M. Luisi, L.D. Anderson, B. Liu, D.S. Balser, T.M. Bania, T.V. Wenger, L.M. Haffner. 2020. "The GBT Diffuse Ionized Gas Survey: Tracing the Diffuse Ionized Gas around the Giant Hii Region W43" The Astrophysical Journal: an international review of astronomy and astronomical physics, Volume 889, Issue 2, pp.96-96. https://doi.org/10.3847/1538-4357/ab643e
Abstract
The Green Bank Telescope Diffuse Ionized Gas Survey (GDIGS) is a fully sampled radio recombination line (RRL) survey of the inner Galaxy at C-band (4–8 GHz). We average together ∼15 Hnα RRLs within the receiver bandpass to improve the spectral signal-to-noise ratio. The average beam size for the RRL observations at these frequencies is ∼2′. We grid these data to have spatial and velocity spacings of 30″ and 0.5 kms^-, respectively. Here we discuss the first RRL data from GDIGS: a 6 deg2 area surrounding the Galactic H II region complex W43. We attempt to create a map devoid of emission from discrete H II regions and detect RRL emission from the diffuse ionized gas (DIG) across nearly the entire mapped area. We estimate the intensity of the DIG emission by a simple empirical model, taking only the H II region locations, angular sizes, and RRL intensities into account. The DIG emission is predominantly found at two distinct velocities: ∼40 and ∼100 kms^-1. While the 100 kms^-1 component is associated with W43 at a distance of ∼6 kpc, the origin of the 40 km^-1 component is less clear. Since the distribution of the 40 km^-1emission cannot be adequately explained by ionizing sources at the same velocity, we hypothesize that the plasma at the two velocity components is interacting, placing the 40 kms^-1DIG at a similar distance as the 100 kms^-1 emission. We find a correlation between dust temperature and integrated RRL intensity, suggesting that the same radiation field that heats the dust also maintains the ionization of the DIG.