GLACE survey: OSIRIS/GTC Tuneable Filter H$alpha$ imaging of the rich galaxy cluster ZwCl 0024.0+1652 at z = 0.395. Part I -- Survey presentation, TF data reduction techniques and catalogue


Abstract in English

The cores of clusters at 0 $lesssim$ z $lesssim$ 1 are dominated by quiescent early-type galaxies, whereas the field is dominated by star-forming late-type ones. Galaxy properties, notably the star formation (SF) ability, are altered as they fall into overdense regions. The critical issues to understand this evolution are how the truncation of SF is connected to the morphological transformation and the responsible physical mechanism. The GaLAxy Cluster Evolution Survey (GLACE) is conducting a study on the variation of galaxy properties (SF, AGN, morphology) as a function of environment in a representative sample of clusters. A deep survey of emission line galaxies (ELG) is being performed, mapping a set of optical lines ([OII], [OIII], H$beta$ and H$alpha$/[NII]) in several clusters at z $sim$ 0.40, 0.63 and 0.86. Using the Tunable Filters (TF) of OSIRIS/GTC, GLACE applies the technique of TF tomography: for each line, a set of images at different wavelengths are taken through the TF, to cover a rest frame velocity range of several thousands km/s. The first GLACE results target the H$alpha$/[NII] lines in the cluster ZwCl 0024.0+1652 at z = 0.395 covering $sim$ 2 $times$ r$_{vir}$. We discuss the techniques devised to process the TF tomography observations to generate the catalogue of H$alpha$ emitters of 174 unique cluster sources down to a SFR below 1 M$_{odot}$/yr. The AGN population is discriminated using different diagnostics and found to be $sim$ 37% of the ELG population. The median SFR is 1.4 M$_{odot}$/yr. We have studied the spatial distribution of ELG, confirming the existence of two components in the redshift space. Finally, we have exploited the outstanding spectral resolution of the TF to estimate the cluster mass from ELG dynamics, finding M$_{200}$ = 4.1 $times$ 10$^{14}$ M$_{odot} h^{-1}$, in agreement with previous weak-lensing estimates.

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