Galaxy And Mass Assembly (GAMA): Spectroscopic analysis

A. M. Hopkins (1); S. P. Driver (2,3); S. Brough (1); M. S. Owers (1),; A. E. Bauer (1); M. L. P. Gunawardhana (1,4); M. E. Cluver (1); M. Colless; (1); C. Foster (5); M. A. Lara-Lopez (1); I. Roseboom (6); R. Sharp (7); O.; Steele (8); D. Thomas (8); I. K. Baldry (9); M. J. I. Brown (10); J. Liske; (11); P. Norberg (12); A. S. G. Robotham (2,3); S. Bamford (13); J.; Bland-Hawthorn (4); M. J. Drinkwater (14); J. Loveday (15); M. Meyer (2); J.; A. Peacock (6); R. Tuffs (16); N. Agius (17); M. Alpaslan (2,3); E. Andrae; (16); E. Cameron (16); S. Cole (12); J. H. Y. Ching (4); L. Christodoulou; (15); C. Conselice (13); S. Croom (4); N. J. G. Cross (6); R. De Propris; (18); J. Delhaize (2); L. Dunne (19); S. Eales (20); S. Ellis (1); C. S.; Frenk (12); A. Graham (21); M. W. Grootes (16); B. Haussler (13); C. Heymans; (6); D. Hill (3); B. Hoyle (22); M. Hudson (23); M. Jarvis (24,25); J.; Johansson (26); D. H. Jones (10); E. van Kampen (11); L. Kelvin (2,3); K.; Kuijken (27); A. Lopez-Sanchez (1,28); S. Maddox (19); B. Madore (29); C.; Maraston (8); T. McNaught-Roberts (12); R. C. Nichol (8); S. Oliver (15); H.; Parkinson (6); S. Penny (10); S. Phillipps (30); K. A. Pimbblet (10); T.; Ponman (31); C. C. Popescu (17); M. Prescott (25); R. Proctor (32); E. M.; Sadler (4); A. E. Sansom (17); M. Seibert (29); L. Staveley-Smith (2); W.; Sutherland (33); E. Taylor (4); L. Van Waerbeke (34); J. A. Vazquez-Mata; (15); S. Warren (35); D. B. Wijesinghe (4); V. Wild (3); S. Wilkins (24) ((1); Australian Astronomical Observatory; (2) International Centre for Radio; Astronomy Research Australia; (3) University of St Andrews (4) University of; Sydney; (5) European Southern Observatory (6) University of Edinburgh; (7); Australian National University; (8) University of Portsmouth; (9) Liverpool; John Moores University; (10) Monash University; (11) European Southern; Observatory; (12) Durham University; (13) University of Nottingham; (14); University of Queensland; (15) University of Sussex; (16) Max Planck; Institute for Nuclear Physics; (17) University of Central Lancashire; (18); Cerro Tololo Inter-American Observatory; (19) University of Canterbury (20); Cardiff University; (21) Swinburne University; (22) Marti i Franques Spain,; (23) University of Waterloo; (24) University of Oxford; (25) University of; the Western Cape; (26) Max-Planck Institut fuer Astrophysik; (27) Leiden; University; (28) Macquarie University; (29) Carnegie Institution for Science,; (30) University of Bristol; (31) University of Birmingham; (32) Universidade; de Sao Paulo; (33) Queen Mary University London; (34) University of British; Columbia; (35) Imperial College London)

arXiv:1301.7127·astro-ph.CO·June 12, 2015

Galaxy And Mass Assembly (GAMA): Spectroscopic analysis

A. M. Hopkins (1), S. P. Driver (2,3), S. Brough (1), M. S. Owers (1),, A. E. Bauer (1), M. L. P. Gunawardhana (1,4), M. E. Cluver (1), M. Colless, (1), C. Foster (5), M. A. Lara-Lopez (1), I. Roseboom (6), R. Sharp (7), O., Steele (8), D. Thomas (8), I. K. Baldry (9)

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TL;DR

The GAMA survey provides extensive spectroscopic data for nearly 300,000 galaxies, enabling detailed analysis of galaxy properties, emission lines, and activity classifications across a broad redshift range.

Contribution

This paper introduces the GAMA spectroscopic reduction pipeline and presents the first comprehensive analysis of emission and absorption features in a large galaxy sample.

Findings

01

Luminosity dependence of the Balmer decrement confirmed

02

Variation of Balmer decrement with galaxy mass and redshift analyzed

03

Spectral diagnostic diagrams used to distinguish star formation and nuclear activity

Abstract

The Galaxy And Mass Assembly (GAMA) survey is a multiwavelength photometric and spectroscopic survey, using the AAOmega spectrograph on the Anglo-Australian Telescope to obtain spectra for up to ~300000 galaxies over 280 square degrees, to a limiting magnitude of r_pet < 19.8 mag. The target galaxies are distributed over 0<z<0.5 with a median redshift of z~0.2, although the redshift distribution includes a small number of systems, primarily quasars, at higher redshifts, up to and beyond z=1. The redshift accuracy ranges from sigma_v~50km/s to sigma_v~100km/s depending on the signal-to-noise of the spectrum. Here we describe the GAMA spectroscopic reduction and analysis pipeline. We present the steps involved in taking the raw two-dimensional spectroscopic images through to flux-calibrated one-dimensional spectra. The resulting GAMA spectra cover an observed wavelength range of…

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