Direct observational evidence for a large transient galaxy population in groups at 0.85 <z <1

M.L. Balogh; S.L. Mcgee; D.J. Wilman; A. Finoguenov; L.C. Parker; J.L. Connelly; J.S. Mulchaey; R.G. Bower; M. Tanaka; S. Giodini

doi:10.1111/j.1365-2966.2010.18052.x

Direct observational evidence for a large transient galaxy population in groups at 0.85 <z <1

M.L. Balogh, S.L. Mcgee, D.J. Wilman, A. Finoguenov, L.C. Parker, J.L. Connelly, J.S. Mulchaey, R.G. Bower, M. Tanaka, S. Giodini

Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

58 Citations (Scopus)

Abstract

We introduce our survey of galaxy groups at 0.85 < z < 1, as an extension of the Group Environment and Evolution Collaboration. Here we present the first results, based on Gemini GMOS-S nod-and-shuffle spectroscopy of seven galaxy groups selected from spectroscopically confirmed, extended XMM detections in COSMOS. We use photometric redshifts to select potential group members for spectroscopy, and target galaxies with r < 24.75. In total, we have over 100 confirmed group members, and four of the groups have >15 members. The dynamical mass estimates are in good agreement with the masses estimated from the X-ray luminosity, with most of the groups having 13 < log M_dyn/M_⊙ < 14. We compute stellar masses by template-fitting the spectral energy distributions; our spectroscopic sample is statistically complete for all galaxies with M_star≳ 10^10.1 M_⊙, and for blue galaxies we sample masses as low as M_star∼ 10^8.8M_⊙. The fraction of total mass in galaxy starlight spans a range of 0.25–3 per cent, for the six groups with reliable mass determinations. Like lower redshift groups, these systems are dominated by red galaxies, at all stellar masses M_star > 10^10.1 M_⊙. A few group galaxies inhabit the ‘blue cloud’ that dominates the surrounding field; instead, we find a large and possibly distinct population of galaxies with intermediate colours. The ‘green valley’ that exists at low redshift is instead well populated in these groups, containing ∼30 per cent of the galaxies. These do not appear to be exceptionally dusty galaxies, and about half show prominent Balmer absorption lines. Furthermore, their Hubble Space Telescope morphologies appear to be intermediate between those of red-sequence and blue-cloud galaxies of the same stellar mass. Unlike red-sequence galaxies, most of the green galaxies have a disc component, but one that is smaller and less structured than discs found in the blue cloud. We postulate that these are a transient population, migrating from the blue cloud to the red sequence, with a star formation rate that declines with an exponential time-scale 0.6 < τ < 2 Gyr. Such galaxies may not be exclusive to the group environment, as we find examples also amongst the non-members. However, their prominence among the group galaxy population, and the marked lack of blue, star-forming galaxies, provides evidence that the group environment either directly reduces star formation in member galaxies or at least prevents its rejuvenation during the normal cycle of galaxy evolution.

Original language	English
Pages (from-to)	2303-2317
Number of pages	15
Journal	Royal Astronomical Society. Monthly Notices
Volume	412
Issue number	4
Early online date	8 Apr 2011
DOIs	https://doi.org/10.1111/j.1365-2966.2010.18052.x
Publication status	Published - 21 Apr 2011

Bibliographical note

Export Date: 15 August 2017

CODEN: MNRAA

Correspondence Address: Balogh, M.L.; Department of Physics and Astronomy, University of Waterloo, Waterloo, ON N2L 3G1, Canada; email: mbalogh@uwaterloo.ca

References: Baldry, I.K., Balogh, M.L., Bower, R.G., Glazebrook, K., Nichol, R.C., Bamford, S.P., Budavari, T., (2006) MNRAS, 373, p. 469; Balogh, M.L., Morris, S.L., Yee, H.K.C., Carlberg, R.G., Ellingson, E., (1997) ApJ, 488, pp. L75; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., Couch, W.J., Smail, I., Bower, R.G., Glazebrook, K., (2002) MNRAS, 335, p. 10; Balogh, M.L., (2004) MNRAS, 348, p. 1355; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., Mazzotta, P., Bower, R.G., Eke, V., Bourdin, H., Lu, T., Theuns, T., (2010) MNRAS, , in press (doi:) (arXiv:1011.0602); Beers, T.C., Flynn, K., Gebhardt, K., (1990) AJ, 100, p. 32; Bell, E.F., Zheng, X.Z., Papovich, C., Borch, A., Wolf, C., Meisenheimer, K., (2007) ApJ, 663, p. 834; Blanton, M.R., Roweis, S., (2007) AJ, 133, p. 734; Bower, R.G., Benson, A.J., Malbon, R., Helly, J.C., Frenk, C.S., Baugh, C.M., Cole, S., Lacey, C.G., (2006) MNRAS, 370, p. 645; Bower, R.G., McCarthy, I.G., Benson, A.J., (2008) MNRAS, 390, p. 1399; Bruzual, G., Charlot, S., (2003) MNRAS, 344, p. 1000; Capak, P., (2007) ApJS, 172, p. 99; Cardamone, C.N., Urry, C.M., Schawinski, K., Treister, E., Brammer, G., Gawiser, E., (2010) ApJ, 721, pp. L38; Chabrier, G., (2003) PASP, 115, p. 763; Charlot, S., Fall, S.M., (2000) ApJ, 539, p. 718; Cooper, M.C., (2008) MNRAS, 383, p. 1058; Cooper, M.C., (2010) MNRAS, 409, p. 337; Cowie, L.L., Songaila, A., Hu, E.M., Cohen, J.G., (1996) AJ, 112, p. 839; Croton, D.J., (2006) MNRAS, 365, p. 11; Cucciati, O., (2010) A&A, 524, pp. A2; Davis, M., (2003) Discoveries and Research Prospects from 6- to 10-Meter-Class Telescopes II, 4834, p. 161. , in Guhathakurta P., ed., Proc. SPIE, SPIE, Bellingham; Davis, M., (2007) ApJ, 660, pp. L1; De Lucia, G., Poggianti, B.M., Halliday, C., Milvang-Jensen, B., Noll, S., Smail, I., Zaritsky, D., (2009) MNRAS, 400, p. 68; Dressler, A., Oemler Jr, A., Poggianti, B.M., Smail, I., Trager, S., Shectman, S.A., Couch, W.J., Ellis, R.S., (2004) ApJ, 617, p. 867; Elbaz, D., (2007) A&A, 468, p. 33; Ellingson, E., Lin, H., Yee, H.K.C., Carlberg, R.G., (2001) ApJ, 547, p. 609; Elvis, M., (2009) ApJS, 184, p. 158; Finoguenov, A., (2007) ApJS, 172, p. 182; Finoguenov, A., (2009) ApJ, 704, p. 564; Finoguenov, A., (2010) MNRAS, 403, p. 2063; Font, A.S., (2008) MNRAS, 389, p. 1619; Georgakakis, A., (2008) MNRAS, 385, p. 2049; Gerke, B.F., (2005) ApJ, 625, p. 6; Gilbank, D.G., Balogh, M.L., (2008) MNRAS, 385, pp. L116; Gilbank, D.G., (2010) MNRAS, 405, p. 2419; Giodini, S., (2009) ApJ, 703, p. 982; Glazebrook, K., Bland-Hawthorn, J., (2001) PASP, 113, p. 197; Gomez, P.L., (2003) ApJ, 584, p. 210; Halliday, C., (2004) A&A, 427, p. 397; Hasinger, G., (2007) ApJS, 172, p. 29; Hopkins, A.M., (2004) ApJ, 615, p. 209; Hou, A., Parker, L.C., Harris, W.E., Wilman, D.J., (2009) ApJ, 702, p. 1199; Ideue, Y., (2009) ApJ, 700, p. 971; Ilbert, O., (2009) ApJ, 690, p. 1236; Iovino, A., (2010) A&A, 509, pp. A40; Jeltema, T.E., (2009) MNRAS, 399, p. 715; Juneau, S., (2005) ApJ, 619, pp. L135; Kawata, D., Mulchaey, J.S., (2008) ApJ, 672, pp. L103; Knobel, C., (2009) ApJ, 697, p. 1842; Kocevski, D.D., (2010), preprint (arXiv e-prints); Koopmann, R.A., Kenney, J.D.P., (2004) ApJ, 613, p. 866; Larson, R.B., Tinsley, B.M., Caldwell, C.N., (1980) ApJ, 237, p. 692; Leauthaud, A., (2010) ApJ, 709, p. 97; Lewis, I.J., (2002) MNRAS, 333, p. 279; Li, I., (2010) MNRAS, , in press (doi:) (arXiv:1010.1447); Lilly, S.J., Le Fevre, O., Hammer, F., Crampton, D., (1996) ApJ, 460, pp. L1; Lilly, S.J., (2007) ApJS, 172, p. 70; Lilly, S.J., (2009) ApJS, 184, p. 218; Łokas, E.L., Mamon, G.A., (2001) MNRAS, 321, p. 155; Lu, T., Gilbank, D.G., Balogh, M.L., Bognat, A., (2009) MNRAS, 399, p. 1858; McCarthy, I.G., Frenk, C.S., Font, A.S., Lacey, C.G., Bower, R.G., Mitchell, N.L., Balogh, M.L., Theuns, T., (2008) MNRAS, 383, p. 593; McGee, S.L., Balogh, M.L., Bower, R.G., Font, A.S., McCarthy, I.G., (2009) MNRAS, 400, p. 937; McGee, S., Balogh, M., Wilman, D., Bower, R., Mulchaey, J., Parker, L., Oemler, A., (2010) MNRAS, , in press (arXiv:1012.2388); Maier, C., (2009) ApJ, 694, p. 1099; Maraston, C., Daddi, E., Renzini, A., Cimatti, A., Dickinson, M., Papovich, C., Pasquali, A., Pirzkal, N., (2006) ApJ, 652, p. 85; Martin, D.C., (2007) ApJS, 173, p. 342; Moore, B., Katz, N., Lake, G., Dressler, A., Oemler, A., (1996) Nat, 379, p. 613; Muzzin, A., Wilson, G., Lacy, M., Yee, H.K.C., Stanford, S.A., (2008) ApJ, 686, p. 966; Noeske, K.G., (2007) ApJ, 660, pp. L43; Noeske, K.G., (2007) ApJ, 660, pp. L47; Peng, Y., (2010) ApJ, 721, p. 193; Poggianti, B.M., Smail, I., Dressler, A., Couch, W.J., Barger, A.J., Butcher, H., Ellis, R.S., Oemler, A.J., (1999) ApJ, 518, p. 576; Poggianti, B., (2006) ApJ, 642, p. 188; Poggianti, B.M., (2008) ApJ, 684, p. 888; Poggianti, B.M., (2009) ApJ, 693, p. 112; Quilis, V., Moore, B., Bower, R., (2000) Sci, 288, p. 1617; Rieke, G.H., Alonso-Herrero, A., Weiner, B.J., Pérez-González, P.G., Blaylock, M., Donley, J.L., Marcillac, D., (2009) ApJ, 692, p. 556; Rykoff, E.S., (2008) MNRAS, 387, pp. L28; Salim, S., (2007) ApJS, 173, p. 267; Sanders, D.B., (2007) ApJS, 172, p. 86; Scoville, N., (2007) ApJS, 172, p. 38; Scoville, N., (2007) ApJS, 172, p. 1; Skibba, R.A., Sheth, R.K., (2009) MNRAS, 392, p. 1080; Sobral, D., Best, P., Smail, I., Geach, J., Cirasuolo, M., Garn, T., Dalton, G.B., (2011) MNRAS, 411, p. 675; Tonry, J., Davis, M., (1979) AJ, 84, p. 1511; Vulcani, B., Poggianti, B.M., Finn, R.A., Rudnick, G., Desai, V., Bamford, S., (2010) ApJ, 710, pp. L1; Weinmann, S.M., van den, B.F.C., Yang, X., Mo, H.J., (2006) MNRAS, 366, p. 2; Wilman, D.J., Balogh, M.L., Bower, R.G., Mulchaey, J.S., Oemler, A., Carlberg, R.G., Morris, S.L., Whitaker, R.J., (2005) MNRAS, 358, p. 71; Wilman, D.J., (2005) MNRAS, 358, p. 88; Wolf, C., Gray, M.E., Meisenheimer, K., (2005) A&A, 443, p. 435; Xue, Y.Q., (2010) ApJ, 720, p. 368; Yan, R., (2009) MNRAS, 398, p. 735

Keywords

Galaxies: clusters: general

Access to Document

10.1111/j.1365-2966.2010.18052.xLicence: None: All rights reserved

Cite this

Balogh, M. L., Mcgee, S. L., Wilman, D. J., Finoguenov, A., Parker, L. C., Connelly, J. L., Mulchaey, J. S., Bower, R. G., Tanaka, M., & Giodini, S. (2011). Direct observational evidence for a large transient galaxy population in groups at 0.85 <z <1. Royal Astronomical Society. Monthly Notices, 412(4), 2303-2317. Advance online publication. https://doi.org/10.1111/j.1365-2966.2010.18052.x

@article{128d150ce2d0465383191d01b7c93433,

title = "Direct observational evidence for a large transient galaxy population in groups at 0.85 <z <1",

abstract = "We introduce our survey of galaxy groups at 0.85 < z < 1, as an extension of the Group Environment and Evolution Collaboration. Here we present the first results, based on Gemini GMOS-S nod-and-shuffle spectroscopy of seven galaxy groups selected from spectroscopically confirmed, extended XMM detections in COSMOS. We use photometric redshifts to select potential group members for spectroscopy, and target galaxies with r < 24.75. In total, we have over 100 confirmed group members, and four of the groups have >15 members. The dynamical mass estimates are in good agreement with the masses estimated from the X-ray luminosity, with most of the groups having 13 < log Mdyn/M⊙ < 14. We compute stellar masses by template-fitting the spectral energy distributions; our spectroscopic sample is statistically complete for all galaxies with Mstar≳ 1010.1 M⊙, and for blue galaxies we sample masses as low as Mstar∼ 108.8 M⊙. The fraction of total mass in galaxy starlight spans a range of 0.25–3 per cent, for the six groups with reliable mass determinations. Like lower redshift groups, these systems are dominated by red galaxies, at all stellar masses Mstar > 1010.1 M⊙. A few group galaxies inhabit the {\textquoteleft}blue cloud{\textquoteright} that dominates the surrounding field; instead, we find a large and possibly distinct population of galaxies with intermediate colours. The {\textquoteleft}green valley{\textquoteright} that exists at low redshift is instead well populated in these groups, containing ∼30 per cent of the galaxies. These do not appear to be exceptionally dusty galaxies, and about half show prominent Balmer absorption lines. Furthermore, their Hubble Space Telescope morphologies appear to be intermediate between those of red-sequence and blue-cloud galaxies of the same stellar mass. Unlike red-sequence galaxies, most of the green galaxies have a disc component, but one that is smaller and less structured than discs found in the blue cloud. We postulate that these are a transient population, migrating from the blue cloud to the red sequence, with a star formation rate that declines with an exponential time-scale 0.6 < τ < 2 Gyr. Such galaxies may not be exclusive to the group environment, as we find examples also amongst the non-members. However, their prominence among the group galaxy population, and the marked lack of blue, star-forming galaxies, provides evidence that the group environment either directly reduces star formation in member galaxies or at least prevents its rejuvenation during the normal cycle of galaxy evolution.",

keywords = "Galaxies: clusters: general",

author = "M.L. Balogh and S.L. Mcgee and D.J. Wilman and A. Finoguenov and L.C. Parker and J.L. Connelly and J.S. Mulchaey and R.G. Bower and M. Tanaka and S. Giodini",

note = "Export Date: 15 August 2017 CODEN: MNRAA Correspondence Address: Balogh, M.L.; Department of Physics and Astronomy, University of Waterloo, Waterloo, ON N2L 3G1, Canada; email: mbalogh@uwaterloo.ca References: Baldry, I.K., Balogh, M.L., Bower, R.G., Glazebrook, K., Nichol, R.C., Bamford, S.P., Budavari, T., (2006) MNRAS, 373, p. 469; Balogh, M.L., Morris, S.L., Yee, H.K.C., Carlberg, R.G., Ellingson, E., (1997) ApJ, 488, pp. L75; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., Couch, W.J., Smail, I., Bower, R.G., Glazebrook, K., (2002) MNRAS, 335, p. 10; Balogh, M.L., (2004) MNRAS, 348, p. 1355; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., Mazzotta, P., Bower, R.G., Eke, V., Bourdin, H., Lu, T., Theuns, T., (2010) MNRAS, , in press (doi:) (arXiv:1011.0602); Beers, T.C., Flynn, K., Gebhardt, K., (1990) AJ, 100, p. 32; Bell, E.F., Zheng, X.Z., Papovich, C., Borch, A., Wolf, C., Meisenheimer, K., (2007) ApJ, 663, p. 834; Blanton, M.R., Roweis, S., (2007) AJ, 133, p. 734; Bower, R.G., Benson, A.J., Malbon, R., Helly, J.C., Frenk, C.S., Baugh, C.M., Cole, S., Lacey, C.G., (2006) MNRAS, 370, p. 645; Bower, R.G., McCarthy, I.G., Benson, A.J., (2008) MNRAS, 390, p. 1399; Bruzual, G., Charlot, S., (2003) MNRAS, 344, p. 1000; Capak, P., (2007) ApJS, 172, p. 99; Cardamone, C.N., Urry, C.M., Schawinski, K., Treister, E., Brammer, G., Gawiser, E., (2010) ApJ, 721, pp. L38; Chabrier, G., (2003) PASP, 115, p. 763; Charlot, S., Fall, S.M., (2000) ApJ, 539, p. 718; Cooper, M.C., (2008) MNRAS, 383, p. 1058; Cooper, M.C., (2010) MNRAS, 409, p. 337; Cowie, L.L., Songaila, A., Hu, E.M., Cohen, J.G., (1996) AJ, 112, p. 839; Croton, D.J., (2006) MNRAS, 365, p. 11; Cucciati, O., (2010) A&A, 524, pp. A2; Davis, M., (2003) Discoveries and Research Prospects from 6- to 10-Meter-Class Telescopes II, 4834, p. 161. , in Guhathakurta P., ed., Proc. SPIE, SPIE, Bellingham; Davis, M., (2007) ApJ, 660, pp. L1; De Lucia, G., Poggianti, B.M., Halliday, C., Milvang-Jensen, B., Noll, S., Smail, I., Zaritsky, D., (2009) MNRAS, 400, p. 68; Dressler, A., Oemler Jr, A., Poggianti, B.M., Smail, I., Trager, S., Shectman, S.A., Couch, W.J., Ellis, R.S., (2004) ApJ, 617, p. 867; Elbaz, D., (2007) A&A, 468, p. 33; Ellingson, E., Lin, H., Yee, H.K.C., Carlberg, R.G., (2001) ApJ, 547, p. 609; Elvis, M., (2009) ApJS, 184, p. 158; Finoguenov, A., (2007) ApJS, 172, p. 182; Finoguenov, A., (2009) ApJ, 704, p. 564; Finoguenov, A., (2010) MNRAS, 403, p. 2063; Font, A.S., (2008) MNRAS, 389, p. 1619; Georgakakis, A., (2008) MNRAS, 385, p. 2049; Gerke, B.F., (2005) ApJ, 625, p. 6; Gilbank, D.G., Balogh, M.L., (2008) MNRAS, 385, pp. L116; Gilbank, D.G., (2010) MNRAS, 405, p. 2419; Giodini, S., (2009) ApJ, 703, p. 982; Glazebrook, K., Bland-Hawthorn, J., (2001) PASP, 113, p. 197; Gomez, P.L., (2003) ApJ, 584, p. 210; Halliday, C., (2004) A&A, 427, p. 397; Hasinger, G., (2007) ApJS, 172, p. 29; Hopkins, A.M., (2004) ApJ, 615, p. 209; Hou, A., Parker, L.C., Harris, W.E., Wilman, D.J., (2009) ApJ, 702, p. 1199; Ideue, Y., (2009) ApJ, 700, p. 971; Ilbert, O., (2009) ApJ, 690, p. 1236; Iovino, A., (2010) A&A, 509, pp. A40; Jeltema, T.E., (2009) MNRAS, 399, p. 715; Juneau, S., (2005) ApJ, 619, pp. L135; Kawata, D., Mulchaey, J.S., (2008) ApJ, 672, pp. L103; Knobel, C., (2009) ApJ, 697, p. 1842; Kocevski, D.D., (2010), preprint (arXiv e-prints); Koopmann, R.A., Kenney, J.D.P., (2004) ApJ, 613, p. 866; Larson, R.B., Tinsley, B.M., Caldwell, C.N., (1980) ApJ, 237, p. 692; Leauthaud, A., (2010) ApJ, 709, p. 97; Lewis, I.J., (2002) MNRAS, 333, p. 279; Li, I., (2010) MNRAS, , in press (doi:) (arXiv:1010.1447); Lilly, S.J., Le Fevre, O., Hammer, F., Crampton, D., (1996) ApJ, 460, pp. L1; Lilly, S.J., (2007) ApJS, 172, p. 70; Lilly, S.J., (2009) ApJS, 184, p. 218; {\L}okas, E.L., Mamon, G.A., (2001) MNRAS, 321, p. 155; Lu, T., Gilbank, D.G., Balogh, M.L., Bognat, A., (2009) MNRAS, 399, p. 1858; McCarthy, I.G., Frenk, C.S., Font, A.S., Lacey, C.G., Bower, R.G., Mitchell, N.L., Balogh, M.L., Theuns, T., (2008) MNRAS, 383, p. 593; McGee, S.L., Balogh, M.L., Bower, R.G., Font, A.S., McCarthy, I.G., (2009) MNRAS, 400, p. 937; McGee, S., Balogh, M., Wilman, D., Bower, R., Mulchaey, J., Parker, L., Oemler, A., (2010) MNRAS, , in press (arXiv:1012.2388); Maier, C., (2009) ApJ, 694, p. 1099; Maraston, C., Daddi, E., Renzini, A., Cimatti, A., Dickinson, M., Papovich, C., Pasquali, A., Pirzkal, N., (2006) ApJ, 652, p. 85; Martin, D.C., (2007) ApJS, 173, p. 342; Moore, B., Katz, N., Lake, G., Dressler, A., Oemler, A., (1996) Nat, 379, p. 613; Muzzin, A., Wilson, G., Lacy, M., Yee, H.K.C., Stanford, S.A., (2008) ApJ, 686, p. 966; Noeske, K.G., (2007) ApJ, 660, pp. L43; Noeske, K.G., (2007) ApJ, 660, pp. L47; Peng, Y., (2010) ApJ, 721, p. 193; Poggianti, B.M., Smail, I., Dressler, A., Couch, W.J., Barger, A.J., Butcher, H., Ellis, R.S., Oemler, A.J., (1999) ApJ, 518, p. 576; Poggianti, B., (2006) ApJ, 642, p. 188; Poggianti, B.M., (2008) ApJ, 684, p. 888; Poggianti, B.M., (2009) ApJ, 693, p. 112; Quilis, V., Moore, B., Bower, R., (2000) Sci, 288, p. 1617; Rieke, G.H., Alonso-Herrero, A., Weiner, B.J., P{\'e}rez-Gonz{\'a}lez, P.G., Blaylock, M., Donley, J.L., Marcillac, D., (2009) ApJ, 692, p. 556; Rykoff, E.S., (2008) MNRAS, 387, pp. L28; Salim, S., (2007) ApJS, 173, p. 267; Sanders, D.B., (2007) ApJS, 172, p. 86; Scoville, N., (2007) ApJS, 172, p. 38; Scoville, N., (2007) ApJS, 172, p. 1; Skibba, R.A., Sheth, R.K., (2009) MNRAS, 392, p. 1080; Sobral, D., Best, P., Smail, I., Geach, J., Cirasuolo, M., Garn, T., Dalton, G.B., (2011) MNRAS, 411, p. 675; Tonry, J., Davis, M., (1979) AJ, 84, p. 1511; Vulcani, B., Poggianti, B.M., Finn, R.A., Rudnick, G., Desai, V., Bamford, S., (2010) ApJ, 710, pp. L1; Weinmann, S.M., van den, B.F.C., Yang, X., Mo, H.J., (2006) MNRAS, 366, p. 2; Wilman, D.J., Balogh, M.L., Bower, R.G., Mulchaey, J.S., Oemler, A., Carlberg, R.G., Morris, S.L., Whitaker, R.J., (2005) MNRAS, 358, p. 71; Wilman, D.J., (2005) MNRAS, 358, p. 88; Wolf, C., Gray, M.E., Meisenheimer, K., (2005) A&A, 443, p. 435; Xue, Y.Q., (2010) ApJ, 720, p. 368; Yan, R., (2009) MNRAS, 398, p. 735",

year = "2011",

month = apr,

day = "21",

doi = "10.1111/j.1365-2966.2010.18052.x",

language = "English",

volume = "412",

pages = "2303--2317",

journal = "Royal Astronomical Society. Monthly Notices",

issn = "0035-8711",

publisher = "SIPRI/Oxford University Press",

number = "4",

}

TY - JOUR

T1 - Direct observational evidence for a large transient galaxy population in groups at 0.85 <z <1

AU - Balogh, M.L.

AU - Mcgee, S.L.

AU - Wilman, D.J.

AU - Finoguenov, A.

AU - Parker, L.C.

AU - Connelly, J.L.

AU - Mulchaey, J.S.

AU - Bower, R.G.

AU - Tanaka, M.

AU - Giodini, S.

N1 - Export Date: 15 August 2017 CODEN: MNRAA Correspondence Address: Balogh, M.L.; Department of Physics and Astronomy, University of Waterloo, Waterloo, ON N2L 3G1, Canada; email: mbalogh@uwaterloo.ca References: Baldry, I.K., Balogh, M.L., Bower, R.G., Glazebrook, K., Nichol, R.C., Bamford, S.P., Budavari, T., (2006) MNRAS, 373, p. 469; Balogh, M.L., Morris, S.L., Yee, H.K.C., Carlberg, R.G., Ellingson, E., (1997) ApJ, 488, pp. L75; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., Couch, W.J., Smail, I., Bower, R.G., Glazebrook, K., (2002) MNRAS, 335, p. 10; Balogh, M.L., (2004) MNRAS, 348, p. 1355; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., Mazzotta, P., Bower, R.G., Eke, V., Bourdin, H., Lu, T., Theuns, T., (2010) MNRAS, , in press (doi:) (arXiv:1011.0602); Beers, T.C., Flynn, K., Gebhardt, K., (1990) AJ, 100, p. 32; Bell, E.F., Zheng, X.Z., Papovich, C., Borch, A., Wolf, C., Meisenheimer, K., (2007) ApJ, 663, p. 834; Blanton, M.R., Roweis, S., (2007) AJ, 133, p. 734; Bower, R.G., Benson, A.J., Malbon, R., Helly, J.C., Frenk, C.S., Baugh, C.M., Cole, S., Lacey, C.G., (2006) MNRAS, 370, p. 645; Bower, R.G., McCarthy, I.G., Benson, A.J., (2008) MNRAS, 390, p. 1399; Bruzual, G., Charlot, S., (2003) MNRAS, 344, p. 1000; Capak, P., (2007) ApJS, 172, p. 99; Cardamone, C.N., Urry, C.M., Schawinski, K., Treister, E., Brammer, G., Gawiser, E., (2010) ApJ, 721, pp. L38; Chabrier, G., (2003) PASP, 115, p. 763; Charlot, S., Fall, S.M., (2000) ApJ, 539, p. 718; Cooper, M.C., (2008) MNRAS, 383, p. 1058; Cooper, M.C., (2010) MNRAS, 409, p. 337; Cowie, L.L., Songaila, A., Hu, E.M., Cohen, J.G., (1996) AJ, 112, p. 839; Croton, D.J., (2006) MNRAS, 365, p. 11; Cucciati, O., (2010) A&A, 524, pp. A2; Davis, M., (2003) Discoveries and Research Prospects from 6- to 10-Meter-Class Telescopes II, 4834, p. 161. , in Guhathakurta P., ed., Proc. SPIE, SPIE, Bellingham; Davis, M., (2007) ApJ, 660, pp. L1; De Lucia, G., Poggianti, B.M., Halliday, C., Milvang-Jensen, B., Noll, S., Smail, I., Zaritsky, D., (2009) MNRAS, 400, p. 68; Dressler, A., Oemler Jr, A., Poggianti, B.M., Smail, I., Trager, S., Shectman, S.A., Couch, W.J., Ellis, R.S., (2004) ApJ, 617, p. 867; Elbaz, D., (2007) A&A, 468, p. 33; Ellingson, E., Lin, H., Yee, H.K.C., Carlberg, R.G., (2001) ApJ, 547, p. 609; Elvis, M., (2009) ApJS, 184, p. 158; Finoguenov, A., (2007) ApJS, 172, p. 182; Finoguenov, A., (2009) ApJ, 704, p. 564; Finoguenov, A., (2010) MNRAS, 403, p. 2063; Font, A.S., (2008) MNRAS, 389, p. 1619; Georgakakis, A., (2008) MNRAS, 385, p. 2049; Gerke, B.F., (2005) ApJ, 625, p. 6; Gilbank, D.G., Balogh, M.L., (2008) MNRAS, 385, pp. L116; Gilbank, D.G., (2010) MNRAS, 405, p. 2419; Giodini, S., (2009) ApJ, 703, p. 982; Glazebrook, K., Bland-Hawthorn, J., (2001) PASP, 113, p. 197; Gomez, P.L., (2003) ApJ, 584, p. 210; Halliday, C., (2004) A&A, 427, p. 397; Hasinger, G., (2007) ApJS, 172, p. 29; Hopkins, A.M., (2004) ApJ, 615, p. 209; Hou, A., Parker, L.C., Harris, W.E., Wilman, D.J., (2009) ApJ, 702, p. 1199; Ideue, Y., (2009) ApJ, 700, p. 971; Ilbert, O., (2009) ApJ, 690, p. 1236; Iovino, A., (2010) A&A, 509, pp. A40; Jeltema, T.E., (2009) MNRAS, 399, p. 715; Juneau, S., (2005) ApJ, 619, pp. L135; Kawata, D., Mulchaey, J.S., (2008) ApJ, 672, pp. L103; Knobel, C., (2009) ApJ, 697, p. 1842; Kocevski, D.D., (2010), preprint (arXiv e-prints); Koopmann, R.A., Kenney, J.D.P., (2004) ApJ, 613, p. 866; Larson, R.B., Tinsley, B.M., Caldwell, C.N., (1980) ApJ, 237, p. 692; Leauthaud, A., (2010) ApJ, 709, p. 97; Lewis, I.J., (2002) MNRAS, 333, p. 279; Li, I., (2010) MNRAS, , in press (doi:) (arXiv:1010.1447); Lilly, S.J., Le Fevre, O., Hammer, F., Crampton, D., (1996) ApJ, 460, pp. L1; Lilly, S.J., (2007) ApJS, 172, p. 70; Lilly, S.J., (2009) ApJS, 184, p. 218; Łokas, E.L., Mamon, G.A., (2001) MNRAS, 321, p. 155; Lu, T., Gilbank, D.G., Balogh, M.L., Bognat, A., (2009) MNRAS, 399, p. 1858; McCarthy, I.G., Frenk, C.S., Font, A.S., Lacey, C.G., Bower, R.G., Mitchell, N.L., Balogh, M.L., Theuns, T., (2008) MNRAS, 383, p. 593; McGee, S.L., Balogh, M.L., Bower, R.G., Font, A.S., McCarthy, I.G., (2009) MNRAS, 400, p. 937; McGee, S., Balogh, M., Wilman, D., Bower, R., Mulchaey, J., Parker, L., Oemler, A., (2010) MNRAS, , in press (arXiv:1012.2388); Maier, C., (2009) ApJ, 694, p. 1099; Maraston, C., Daddi, E., Renzini, A., Cimatti, A., Dickinson, M., Papovich, C., Pasquali, A., Pirzkal, N., (2006) ApJ, 652, p. 85; Martin, D.C., (2007) ApJS, 173, p. 342; Moore, B., Katz, N., Lake, G., Dressler, A., Oemler, A., (1996) Nat, 379, p. 613; Muzzin, A., Wilson, G., Lacy, M., Yee, H.K.C., Stanford, S.A., (2008) ApJ, 686, p. 966; Noeske, K.G., (2007) ApJ, 660, pp. L43; Noeske, K.G., (2007) ApJ, 660, pp. L47; Peng, Y., (2010) ApJ, 721, p. 193; Poggianti, B.M., Smail, I., Dressler, A., Couch, W.J., Barger, A.J., Butcher, H., Ellis, R.S., Oemler, A.J., (1999) ApJ, 518, p. 576; Poggianti, B., (2006) ApJ, 642, p. 188; Poggianti, B.M., (2008) ApJ, 684, p. 888; Poggianti, B.M., (2009) ApJ, 693, p. 112; Quilis, V., Moore, B., Bower, R., (2000) Sci, 288, p. 1617; Rieke, G.H., Alonso-Herrero, A., Weiner, B.J., Pérez-González, P.G., Blaylock, M., Donley, J.L., Marcillac, D., (2009) ApJ, 692, p. 556; Rykoff, E.S., (2008) MNRAS, 387, pp. L28; Salim, S., (2007) ApJS, 173, p. 267; Sanders, D.B., (2007) ApJS, 172, p. 86; Scoville, N., (2007) ApJS, 172, p. 38; Scoville, N., (2007) ApJS, 172, p. 1; Skibba, R.A., Sheth, R.K., (2009) MNRAS, 392, p. 1080; Sobral, D., Best, P., Smail, I., Geach, J., Cirasuolo, M., Garn, T., Dalton, G.B., (2011) MNRAS, 411, p. 675; Tonry, J., Davis, M., (1979) AJ, 84, p. 1511; Vulcani, B., Poggianti, B.M., Finn, R.A., Rudnick, G., Desai, V., Bamford, S., (2010) ApJ, 710, pp. L1; Weinmann, S.M., van den, B.F.C., Yang, X., Mo, H.J., (2006) MNRAS, 366, p. 2; Wilman, D.J., Balogh, M.L., Bower, R.G., Mulchaey, J.S., Oemler, A., Carlberg, R.G., Morris, S.L., Whitaker, R.J., (2005) MNRAS, 358, p. 71; Wilman, D.J., (2005) MNRAS, 358, p. 88; Wolf, C., Gray, M.E., Meisenheimer, K., (2005) A&A, 443, p. 435; Xue, Y.Q., (2010) ApJ, 720, p. 368; Yan, R., (2009) MNRAS, 398, p. 735

PY - 2011/4/21

Y1 - 2011/4/21

N2 - We introduce our survey of galaxy groups at 0.85 < z < 1, as an extension of the Group Environment and Evolution Collaboration. Here we present the first results, based on Gemini GMOS-S nod-and-shuffle spectroscopy of seven galaxy groups selected from spectroscopically confirmed, extended XMM detections in COSMOS. We use photometric redshifts to select potential group members for spectroscopy, and target galaxies with r < 24.75. In total, we have over 100 confirmed group members, and four of the groups have >15 members. The dynamical mass estimates are in good agreement with the masses estimated from the X-ray luminosity, with most of the groups having 13 < log Mdyn/M⊙ < 14. We compute stellar masses by template-fitting the spectral energy distributions; our spectroscopic sample is statistically complete for all galaxies with Mstar≳ 1010.1 M⊙, and for blue galaxies we sample masses as low as Mstar∼ 108.8 M⊙. The fraction of total mass in galaxy starlight spans a range of 0.25–3 per cent, for the six groups with reliable mass determinations. Like lower redshift groups, these systems are dominated by red galaxies, at all stellar masses Mstar > 1010.1 M⊙. A few group galaxies inhabit the ‘blue cloud’ that dominates the surrounding field; instead, we find a large and possibly distinct population of galaxies with intermediate colours. The ‘green valley’ that exists at low redshift is instead well populated in these groups, containing ∼30 per cent of the galaxies. These do not appear to be exceptionally dusty galaxies, and about half show prominent Balmer absorption lines. Furthermore, their Hubble Space Telescope morphologies appear to be intermediate between those of red-sequence and blue-cloud galaxies of the same stellar mass. Unlike red-sequence galaxies, most of the green galaxies have a disc component, but one that is smaller and less structured than discs found in the blue cloud. We postulate that these are a transient population, migrating from the blue cloud to the red sequence, with a star formation rate that declines with an exponential time-scale 0.6 < τ < 2 Gyr. Such galaxies may not be exclusive to the group environment, as we find examples also amongst the non-members. However, their prominence among the group galaxy population, and the marked lack of blue, star-forming galaxies, provides evidence that the group environment either directly reduces star formation in member galaxies or at least prevents its rejuvenation during the normal cycle of galaxy evolution.

AB - We introduce our survey of galaxy groups at 0.85 < z < 1, as an extension of the Group Environment and Evolution Collaboration. Here we present the first results, based on Gemini GMOS-S nod-and-shuffle spectroscopy of seven galaxy groups selected from spectroscopically confirmed, extended XMM detections in COSMOS. We use photometric redshifts to select potential group members for spectroscopy, and target galaxies with r < 24.75. In total, we have over 100 confirmed group members, and four of the groups have >15 members. The dynamical mass estimates are in good agreement with the masses estimated from the X-ray luminosity, with most of the groups having 13 < log Mdyn/M⊙ < 14. We compute stellar masses by template-fitting the spectral energy distributions; our spectroscopic sample is statistically complete for all galaxies with Mstar≳ 1010.1 M⊙, and for blue galaxies we sample masses as low as Mstar∼ 108.8 M⊙. The fraction of total mass in galaxy starlight spans a range of 0.25–3 per cent, for the six groups with reliable mass determinations. Like lower redshift groups, these systems are dominated by red galaxies, at all stellar masses Mstar > 1010.1 M⊙. A few group galaxies inhabit the ‘blue cloud’ that dominates the surrounding field; instead, we find a large and possibly distinct population of galaxies with intermediate colours. The ‘green valley’ that exists at low redshift is instead well populated in these groups, containing ∼30 per cent of the galaxies. These do not appear to be exceptionally dusty galaxies, and about half show prominent Balmer absorption lines. Furthermore, their Hubble Space Telescope morphologies appear to be intermediate between those of red-sequence and blue-cloud galaxies of the same stellar mass. Unlike red-sequence galaxies, most of the green galaxies have a disc component, but one that is smaller and less structured than discs found in the blue cloud. We postulate that these are a transient population, migrating from the blue cloud to the red sequence, with a star formation rate that declines with an exponential time-scale 0.6 < τ < 2 Gyr. Such galaxies may not be exclusive to the group environment, as we find examples also amongst the non-members. However, their prominence among the group galaxy population, and the marked lack of blue, star-forming galaxies, provides evidence that the group environment either directly reduces star formation in member galaxies or at least prevents its rejuvenation during the normal cycle of galaxy evolution.

KW - Galaxies: clusters: general

UR - http://www.scopus.com/inward/record.url?eid=2-s2.0-79953770140&partnerID=MN8TOARS

U2 - 10.1111/j.1365-2966.2010.18052.x

DO - 10.1111/j.1365-2966.2010.18052.x

M3 - Article

SN - 0035-8711

VL - 412

SP - 2303

EP - 2317

JO - Royal Astronomical Society. Monthly Notices

JF - Royal Astronomical Society. Monthly Notices

IS - 4

ER -

Direct observational evidence for a large transient galaxy population in groups at 0.85 <z <1

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