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Longslit Optical Spectroscopy of Powerful Far-Infrared Galaxies

Published online by Cambridge University Press:  07 August 2017

Lee Armus ,
Timothy M. Heckman  and
George K. Miley
Lee Armus
Affiliation:
Astronomy Program, University of Maryland
Timothy M. Heckman
Affiliation:
Astronomy Program, University of Maryland
George K. Miley
Affiliation:
Space Telescope Science Institute, on leave from Leiden University

Extract

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It has been known since the IRAS mission that there exist galaxies with far-infrared luminosities of 1011–1012Lo, and LFTR/LB = 10–100. Through extensive modelling and observations of HII-region/molecular cloud complexes in the Galaxy, this infrared radiation is believed to be thermal emission from heated dust grains (c.f. review by Stein and Soifer 1983). While starburst models are consistent with the data over a large range in wavelength, direct evidence for sizeable populations of young stars is scarce, and in many cases the presence of an active nucleus either cannot be ruled out, or is required on the basis of energy considerations. In order to better understand the energy source responsible for heating the dust, we have undertaken a spectroscopic survey of galaxies chosen to have far-infrared spectral energy distributions similar to the prototypical class members Arp 220, NGC 6240, NGC 3690, and Mrk 231. It was required that between 25μ and 60μ, α ≤ −1.5, and that between 60μ and 100μ, α ≥ −0.5, where Sv α vα.

Type
Part 7: Dust, Molecules, Infrared and MM Radiation
Information
Symposium - International Astronomical Union , Volume 134: Active Galactic Nuclei , 1989 , pp. 414 - 415
Copyright
Copyright © Kluwer 1989 

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