Efficient satellite quenching at z∼1 from the geec2 spectroscopic survey of galaxy groups

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

doi:10.1093/mnras/stt251

Efficient satellite quenching at z∼1 from the geec2 spectroscopic survey of galaxy groups

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

Physics and Astronomy

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

43 Citations (Scopus)

Abstract

We present deep Gemini Multi-Object Spectrograph-South spectroscopy for 11 galaxy groups at 0.8 < z < 1.0, for galaxies with rAB < 24.75. Our sample is highly complete (>66 per cent) for eight of the 11 groups. Using an optical-near-infrared colour-colour diagram, the galaxies in the sample were separated with a dust insensitive method into three categories: passive (red), star-forming (blue) and intermediate (green). The strongest environmental dependence is observed in the fraction of passive galaxies, which make up only ∼20 per cent of the field in the mass range 1010.3 < Mstar/M⊙ < 1011.0, but are the dominant component of groups. If we assume that the properties of the field are similar to those of the 'pre-accreted' population, the environment quenching efficiency (ερ) is defined as the fraction of field galaxies required to be quenched in order to match the observed red fraction inside groups. The efficiency obtained is ∼0.4, similar to its value in intermediate-density environments locally. While green (intermediate) galaxies represent ∼20 per cent of the star-forming population in both the group and field, at all stellar masses, the average specific star formation rate of the group population is lower by a factor of ∼3. The green population does not show strong Hδ absorption that is characteristic of starburst galaxies. Finally, the high fraction of passive galaxies in groups, when combined with satellite accretion models, require that most accreted galaxies have been affected by their environment. Thus, any delay between accretion and the onset of truncation of star formation (τ) must be ≲ 2 Gyr, shorter than the 3-7 Gyr required to fit data at z 0. The relatively small fraction of intermediate galaxies require that the actual quenching process occurs quickly, with an exponential decay time-scale of τq ≲ 1 Gyr. © 2013 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.

Original language	English
Pages (from-to)	1090-1106
Number of pages	17
Journal	Royal Astronomical Society. Monthly Notices
Volume	431
Issue number	2
DOIs	https://doi.org/10.1093/mnras/stt251
Publication status	Published - 2013

Bibliographical note

Export Date: 15 August 2017

CODEN: MNRAA

Correspondence Address: Mok, A.; Department of Physics and Astronomy, University of Waterloo, Waterloo, ON N2L 3G1, Canada; email: [email protected]

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Keywords

Galaxies: evolution
Galaxies: general
Galaxies: luminosity function, mass function

Access to Document

10.1093/mnras/stt251

https://www.scopus.com/inward/record.uri?eid=2-s2.0-84877062900&doi=10.1093%2fmnras%2fstt251&partnerID=40&md5=6d1855d73041d982b85d2d1471655a9e

Cite this

@article{77071cd8b80b4bbdbee99942cbf4b3e0,

title = "Efficient satellite quenching at z∼1 from the geec2 spectroscopic survey of galaxy groups",

abstract = "We present deep Gemini Multi-Object Spectrograph-South spectroscopy for 11 galaxy groups at 0.8 < z < 1.0, for galaxies with rAB < 24.75. Our sample is highly complete (>66 per cent) for eight of the 11 groups. Using an optical-near-infrared colour-colour diagram, the galaxies in the sample were separated with a dust insensitive method into three categories: passive (red), star-forming (blue) and intermediate (green). The strongest environmental dependence is observed in the fraction of passive galaxies, which make up only ∼20 per cent of the field in the mass range 1010.3 < Mstar/M⊙ < 1011.0, but are the dominant component of groups. If we assume that the properties of the field are similar to those of the 'pre-accreted' population, the environment quenching efficiency (ερ) is defined as the fraction of field galaxies required to be quenched in order to match the observed red fraction inside groups. The efficiency obtained is ∼0.4, similar to its value in intermediate-density environments locally. While green (intermediate) galaxies represent ∼20 per cent of the star-forming population in both the group and field, at all stellar masses, the average specific star formation rate of the group population is lower by a factor of ∼3. The green population does not show strong Hδ absorption that is characteristic of starburst galaxies. Finally, the high fraction of passive galaxies in groups, when combined with satellite accretion models, require that most accreted galaxies have been affected by their environment. Thus, any delay between accretion and the onset of truncation of star formation (τ) must be ≲ 2 Gyr, shorter than the 3-7 Gyr required to fit data at z 0. The relatively small fraction of intermediate galaxies require that the actual quenching process occurs quickly, with an exponential decay time-scale of τq ≲ 1 Gyr. {\textcopyright} 2013 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.",

keywords = "Galaxies: evolution, Galaxies: general, Galaxies: luminosity function, mass function",

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

note = "Export Date: 15 August 2017 CODEN: MNRAA Correspondence Address: Mok, A.; Department of Physics and Astronomy, University of Waterloo, Waterloo, ON N2L 3G1, Canada; email: [email protected] 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., (1999) ApJ, 527, p. 54; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., (2007) MNRAS, 374, p. 1169; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., (2011) MNRAS, 412, p. 2303; Beers, T.C., Flynn, K., Gebhardt, K., (1990) AJ, 100, p. 32; 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., Benson, A.J., Crain, R.A., (2012) MNRAS, 422, p. 2816; Brinchmann, J., Charlot, S., White, S.D.M., Tremonti, C., Kauffmann, G., Heckman, T., Brinkmann, J., (2004) MNRAS, 351, p. 1151; Bruzual, G., From Stars to Galaxies: Building the Pieces to Build Up the Universe (2007) Astron. Soc. Pac., p. 303. , in Vallenari A., Tantalo R., Portinari L., Moretti A., eds, San Francisco; Bruzual, G., Charlot, S., (2003) MNRAS, 344, p. 1000; Capak, P., (2007) ApJS, 172, p. 99; Carlberg, R.G., Yee, H.K.C., Morris, S.L., Lin, H., Hall, P.B., Patton, D.R., Sawicki, M., Shepherd, C.W., (2001) ApJ, 563, p. 736; Chabrier, G., (2003) PASP, 115, p. 763; Chary, R., Elbaz, D., (2001) ApJ, 556, p. 562; Connelly, J.L., (2012) ApJ, 756, p. 139; Cooper, M.C., (2006) MNRAS, 370, p. 198; Cooper, M.C., (2008) MNRAS, 383, p. 1058; Couch, W.J., Sharples, R.M., (1987) MNRAS, 229, p. 423; Cucciati, O., (2010) A&A, 524, pp. A2; Cucciati, O., (2012) A&A, 539, pp. A31; De Lucia, G., Weinmann, S., Poggianti, B.M., Arag{\'o}n-Salamanca, A., Zaritsky, D., (2012) MNRAS, 423, p. 1277; Eke, V.R., (2004) MNRAS, 355, p. 769; Elbaz, D., (2007) A&A, 468, p. 33; Ellingson, E., Lin, H., Yee, H.K.C., Carlberg, R.G., (2001) ApJ, 547, p. 609; Finoguenov, A., (2007) ApJS, 172, p. 182; Finoguenov, A., (2009) ApJ, 704, p. 564; Finoguenov, A., (2010) MNRAS, 403, p. 2063; Geach, J.E., Ellis, R.S., Smail, I., Rawle, T.D., Moran, S.M., (2011) MNRAS, 413, p. 177; Georgakakis, A., (2008) MNRAS, 385, p. 2049; George, M.R., (2011) ApJ, 742, p. 125; George, M.R., (2012) ApJ, 757, p. 2; Gerke, B.F., (2012) ApJ, 751, p. 50; Gilbank, D.G., Baldry, I.K., Balogh, M.L., Glazebrook, K., Bower, R.G., (2010) MNRAS, 405, p. 2594; Giodini, S., (2012) A&A, 538, pp. A104; Glazebrook, K., Bland-Hawthorn, J., (2001) PASP, 113, p. 197; Gr{\"u}tzbauch, R., Conselice, C.J., Varela, J., Bundy, K., Cooper, M.C., Skibba, R., Willmer, C.N.A., (2011) MNRAS, 411, p. 929; Hao, C.-N., Kennicutt, R.C., Johnson, B.D., Calzetti, D., Dale, D.A., Moustakas, J., (2011) ApJ, 741, p. 124; Ilbert, O., (2009) ApJ, 690, p. 1236; Ilbert, O., (2010) ApJ, 709, p. 644; Iovino, A., (2010) A&A, 509, pp. A40; Jeltema, T.E., (2009) MNRAS, 399, p. 715; Karim, A., (2011) ApJ, 730, p. 61; Knobel, C., (2009) ApJ, 697, p. 1842; Knobel, C., (2012) ApJ, 753, p. 121; Knobel, C., (2012), preprint (arXiv:1211.5607); Komatsu, E., (2011) ApJS, 192, p. 18; Labb{\'e}, I., (2005) ApJ, 624, pp. L81; Leauthaud, A., (2012) ApJ, 746, p. 95; Lemaux, B.C., (2012) ApJ, 745, p. 106; Li, I.H., (2011) MNRAS, 411, p. 1869; Li, I.H., Yee, H.K.C., Hsieh, B.C., Gladders, M., (2012) ApJ, 749, p. 150; 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; Magdis, G.E., (2011) A&A, 534, pp. A15; McGee, S.L., Balogh, M.L., Henderson, R.D.E., Wilman, D.J., Bower, R.G., Mulchaey, J.S., Oemler Jr., A., (2008) MNRAS, 387, p. 1605; McGee, S.L., Balogh, M.L., Bower, R.G., Font, A.S., McCarthy, I.G., (2009) MNRAS, 400, p. 937; McGee, S.L., Balogh, M.L., Wilman, D.J., Bower, R.G., Mulchaey, J.S., Parker, L.C., Oemler, A., (2011) MNRAS, 413, p. 996; Muzzin, A., (2012) ApJ, 746, p. 188; Newman, J.A., (2012), preprint (arXiv:1203.3192); Noeske, K.G., (2007) ApJ, 660, pp. L43; Patel, S.G., Kelson, D.D., Holden, B.P., Franx, M., Illingworth, G.D., (2011) ApJ, 735, p. 53; Pell{\'o}, R., (2009) A&A, 508, p. 1173; Peng, Y.-J., (2010) ApJ, 721, p. 193; Peng, Y.-J., Lilly, S.J., Renzini, A., Carollo, M., (2012) ApJ, 757, p. 4; Pozzetti, L., (2010) A&A, 523, pp. A13; Presotto, V., (2012) A&A, 539, pp. A55; Salim, S., (2007) ApJS, 173, p. 267; Salim, S., (2009) ApJ, 700, p. 161; Salmi, F., Daddi, E., Elbaz, D., Sargent, M.T., Dickinson, M., Renzini, A., Bethermin, M., Le Borgne, D., (2012) ApJ, 754, pp. L14; Sanders, D.B., (2007) ApJS, 172, p. 86; Scoville, N., (2007) ApJS, 172, p. 1; Smith, R.J., Lucey, J.R., Price, J., Hudson, M.J., Phillipps, S., (2012) MNRAS, 419, p. 3167; Sobral, D., Best, P.N., Smail, I., Geach, J.E., Cirasuolo, M., Garn, T., Dalton, G.B., (2011) MNRAS, 411, p. 675; Tanaka, M., (2012) PASJ, 64, p. 22; Tinker, J.L., Wetzel, A.R., (2010) ApJ, 719, p. 88; Van Den Bosch, F.C., Aquino, D., Yang, X., Mo, H.J., Pasquali, A., McIntosh, D.H., Weinmann, S.M., Kang, X., (2008) MNRAS, 387, p. 79; Vollmann, K., Eversberg, T., (2006) Astron. Nachr., 327, p. 862; Wetzel, A.R., Tinker, J.L., Conroy, C., Van Den Bosch, F.C., (2012), preprint (arXiv:1206.3571); Whitaker, K.E., Kriek, M., van Dokkum, P.G., Bezanson, R., Brammer, G., Franx, M., Labb{\'e}, I., (2012) ApJ, 745, p. 179; Whitaker, K.E., van Dokkum, P.G., Brammer, G., Franx, M., (2012) ApJ, 754, pp. L29; 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., Oemler Jr., A., Mulchaey, J.S., McGee, S.L., Balogh, M.L., Bower, R.G., (2009) ApJ, 692, p. 298; Wolf, C., Gray, M.E., Meisenheimer, K., (2005) A&A, 443, p. 435",

year = "2013",

doi = "10.1093/mnras/stt251",

language = "English",

volume = "431",

pages = "1090--1106",

journal = "Royal Astronomical Society. Monthly Notices",

issn = "0035-8711",

publisher = "SIPRI/Oxford University Press",

number = "2",

}

TY - JOUR

T1 - Efficient satellite quenching at z∼1 from the geec2 spectroscopic survey of galaxy groups

AU - Mok, A.

AU - Balogh, M.L.

AU - Mcgee, S.L.

AU - Wilman, D.J.

AU - Finoguenov, A.

AU - Tanaka, M.

AU - Giodini, S.

AU - Bower, R.G.

AU - Connelly, J.L.

AU - Hou, A.

AU - Mulchaey, J.S.

AU - Parker, L.C.

N1 - Export Date: 15 August 2017 CODEN: MNRAA Correspondence Address: Mok, A.; Department of Physics and Astronomy, University of Waterloo, Waterloo, ON N2L 3G1, Canada; email: [email protected] 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., (1999) ApJ, 527, p. 54; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., (2007) MNRAS, 374, p. 1169; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., (2011) MNRAS, 412, p. 2303; Beers, T.C., Flynn, K., Gebhardt, K., (1990) AJ, 100, p. 32; 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., Benson, A.J., Crain, R.A., (2012) MNRAS, 422, p. 2816; Brinchmann, J., Charlot, S., White, S.D.M., Tremonti, C., Kauffmann, G., Heckman, T., Brinkmann, J., (2004) MNRAS, 351, p. 1151; Bruzual, G., From Stars to Galaxies: Building the Pieces to Build Up the Universe (2007) Astron. Soc. 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PY - 2013

Y1 - 2013

N2 - We present deep Gemini Multi-Object Spectrograph-South spectroscopy for 11 galaxy groups at 0.8 < z < 1.0, for galaxies with rAB < 24.75. Our sample is highly complete (>66 per cent) for eight of the 11 groups. Using an optical-near-infrared colour-colour diagram, the galaxies in the sample were separated with a dust insensitive method into three categories: passive (red), star-forming (blue) and intermediate (green). The strongest environmental dependence is observed in the fraction of passive galaxies, which make up only ∼20 per cent of the field in the mass range 1010.3 < Mstar/M⊙ < 1011.0, but are the dominant component of groups. If we assume that the properties of the field are similar to those of the 'pre-accreted' population, the environment quenching efficiency (ερ) is defined as the fraction of field galaxies required to be quenched in order to match the observed red fraction inside groups. The efficiency obtained is ∼0.4, similar to its value in intermediate-density environments locally. While green (intermediate) galaxies represent ∼20 per cent of the star-forming population in both the group and field, at all stellar masses, the average specific star formation rate of the group population is lower by a factor of ∼3. The green population does not show strong Hδ absorption that is characteristic of starburst galaxies. Finally, the high fraction of passive galaxies in groups, when combined with satellite accretion models, require that most accreted galaxies have been affected by their environment. Thus, any delay between accretion and the onset of truncation of star formation (τ) must be ≲ 2 Gyr, shorter than the 3-7 Gyr required to fit data at z 0. The relatively small fraction of intermediate galaxies require that the actual quenching process occurs quickly, with an exponential decay time-scale of τq ≲ 1 Gyr. © 2013 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.

AB - We present deep Gemini Multi-Object Spectrograph-South spectroscopy for 11 galaxy groups at 0.8 < z < 1.0, for galaxies with rAB < 24.75. Our sample is highly complete (>66 per cent) for eight of the 11 groups. Using an optical-near-infrared colour-colour diagram, the galaxies in the sample were separated with a dust insensitive method into three categories: passive (red), star-forming (blue) and intermediate (green). The strongest environmental dependence is observed in the fraction of passive galaxies, which make up only ∼20 per cent of the field in the mass range 1010.3 < Mstar/M⊙ < 1011.0, but are the dominant component of groups. If we assume that the properties of the field are similar to those of the 'pre-accreted' population, the environment quenching efficiency (ερ) is defined as the fraction of field galaxies required to be quenched in order to match the observed red fraction inside groups. The efficiency obtained is ∼0.4, similar to its value in intermediate-density environments locally. While green (intermediate) galaxies represent ∼20 per cent of the star-forming population in both the group and field, at all stellar masses, the average specific star formation rate of the group population is lower by a factor of ∼3. The green population does not show strong Hδ absorption that is characteristic of starburst galaxies. Finally, the high fraction of passive galaxies in groups, when combined with satellite accretion models, require that most accreted galaxies have been affected by their environment. Thus, any delay between accretion and the onset of truncation of star formation (τ) must be ≲ 2 Gyr, shorter than the 3-7 Gyr required to fit data at z 0. The relatively small fraction of intermediate galaxies require that the actual quenching process occurs quickly, with an exponential decay time-scale of τq ≲ 1 Gyr. © 2013 The Authors. Published by Oxford University Press on behalf of the Royal Astronomical Society.

KW - Galaxies: evolution

KW - Galaxies: general

KW - Galaxies: luminosity function, mass function

U2 - 10.1093/mnras/stt251

DO - 10.1093/mnras/stt251

M3 - Article

SN - 0035-8711

VL - 431

SP - 1090

EP - 1106

JO - Royal Astronomical Society. Monthly Notices

JF - Royal Astronomical Society. Monthly Notices

IS - 2

ER -

Efficient satellite quenching at z∼1 from the geec2 spectroscopic survey of galaxy groups

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