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Nebular Attenuation in Halpha-selected Star-forming Galaxies at z=0.8 from the NewHalpha Survey

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 Added by Ivelina Momcheva
 Publication date 2012
  fields Physics
and research's language is English




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We present measurements of the dust attenuation of Halpha-selected emission-line galaxies at z=0.8 from the NewHalpha narrowband survey. The analysis is based on deep follow-up spectroscopy with Magellan/IMACS, which captures the strong rest-frame optical emission lines from [OII] lambda 3727 to [OIII] lambda 5007. The spectroscopic sample used in this analysis consists of 341 confirmed Halpha emitters. We place constraints on the AGN fraction using diagnostics which can be applied at intermediate redshift. We find that at least 5% of the objects in our spectroscopic sample can be classified as AGN and 2% are composite, i.e. powered by a combination of star-formation and AGN activity. We measure the dust attenuation for individual objects from the ratios of the higher order Balmer lines. The Hbeta and Hgamma pair of lines is detected with S/N>5 in 55 individual objects and the Hbeta and Hdelta pair is detected in 50 individual objects. We also create stacked spectra to probe the attenuation in objects without individual detections. The median attenuation at Halpha based on the objects with individually detected lines is A(Halpha)=0.9+-1.0 magnitudes, in good agreement with the attenuation found in local samples of star-forming galaxies. We find that the z=0.8 galaxies occupy a similar locus of attenuation as a function of magnitude, mass and SFR as a comparison sample drawn from the SDSS DR4. Both the results from the individual z=0.8 galaxies and from the stacked spectra show consistency with the mass -- attenuation and SFR -- attenuation relations found in the local Universe, indicating that these relations are also applicable at intermediate redshift.



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