Substructure in the most massive GEEC groups: Field-like populations in dynamically active groups

A. Hou; L.C. Parker; D.J. Wilman; S.L. Mcgee; W.E. Harris; J.L. Connelly; M.L. Balogh; J.S. Mulchaey; R.G. Bower

doi:10.1111/j.1365-2966.2012.20586.x

Substructure in the most massive GEEC groups: Field-like populations in dynamically active groups

A. Hou, L.C. Parker, D.J. Wilman, S.L. Mcgee, W.E. Harris, J.L. Connelly, M.L. Balogh, J.S. Mulchaey, R.G. Bower

Physics and Astronomy

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

43 Citations (Scopus)

Abstract

The presence of substructure in galaxy groups and clusters is believed to be a sign of recent galaxy accretion and can be used to probe not only the assembly history of these structures, but also the evolution of their member galaxies. Using the Dressler-Shectman (DS) test, we study substructure in a sample of intermediate-redshift (z∼ 0.4) galaxy groups from the Group Environment and Evolution Collaboration (GEEC) group catalogue. We find that four of the 15 rich GEEC groups, with an average velocity dispersion of ∼525kms -1, are identified as having significant substructure. The identified regions of localized substructure lie on the group outskirts and in some cases appear to be infalling. In a comparison of galaxy properties for the members of groups with and without substructure, we find that the groups with substructure have a significantly higher fraction of blue and star-forming galaxies and a parent colour distribution that resembles that of the field population rather than the overall group population. In addition, we observe correlations between the detection of substructure and other dynamical measures, such as velocity distributions and velocity dispersion profiles. Based on this analysis, we conclude that some galaxy groups contain significant substructure and that these groups have properties and galaxy populations that differ from groups with no detected substructure. These results indicate that the substructure galaxies, which lie preferentially on the group outskirts and could be infalling, do not exhibit signs of environmental effects, since little or no star formation quenching is observed in these systems. © 2012 The Authors Monthly Notices of the Royal Astronomical Society © 2012 RAS.

Original language	English
Pages (from-to)	3594-3611
Number of pages	18
Journal	Royal Astronomical Society. Monthly Notices
Volume	421
Issue number	4
DOIs	https://doi.org/10.1111/j.1365-2966.2012.20586.x
Publication status	Published - 2012

Bibliographical note

Export Date: 15 August 2017

CODEN: MNRAA

Correspondence Address: Hou, A.; Department of Physics and Astronomy, McMaster University, Hamilton ON L8S 4M1, Canada; email: houa2@physics.mcmaster.ca

References: Abadi, M.G., Moore, B., Bower, R.G., (1999) MNRAS, 308, p. 947; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., (2011) MNRAS, 412, p. 2303; Barrena, R., Boschin, W., Girardi, M., Spolaor, M., (2007) A&A, 469, p. 861; Beers, T.C., Geller, M.J., Huchra, J.P., (1982) ApJ, 257, p. 23; Bergond, G., Zepf, S.E., Romanowsky, A.J., Sharples, R.M., Rhode, K.L., (2006) A&A, 448, p. 155; Berlind, A.A., (2006) ApJS, 167, p. 1; Bird, C., (1994) ApJ, 422, p. 480; Bird, C.M., (1994) AJ, 107, p. 1637; Böhringer, H., (2010) A&A, 514, pp. A32; 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; Brough, S., Forbes, D.A., Kilborn, V.A., Couch, W., (2006) MNRAS, 370, p. 1223; Bruzual, G., Charlot, S., (2003) MNRAS, 344, p. 1000; Burgett, W.S., (2004) MNRAS, 352, p. 605; Cameron, E., (2011) PASA, 28, p. 128; 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, 552, p. 427; Charlot, S., Fall, S.M., (2000) ApJ, 539, p. 718; Colless, M., Dunn, A.M., (1996) ApJ, 458, p. 435; D'Agostino, R., Stephens, M., (1986) Goodness-of-fit Techniques, , Marcel Dekker Inc., New York; Diemand, J., Kuhlen, M., Madau, P., Zemp, M., Moore, B., Potter, D., Stadel, J., (2008) Nat, 454, p. 735; Dressler, A., Shectman, S.A., (1988) AJ, 95, p. 985; Dressler, A., (1997) ApJ, 490, p. 577; Efron, B., (1982) The Jackknife, the Bootstrap and Other Resampling Plans, , Society for Industrial and Applied Mathematics, Philadelphia; Eke, V.R., Baugh, C.M., Cole, S., Frenk, C.S., King, H.M., Peacock, J.A., (2005) MNRAS, 362, p. 1233; Finoguenov, A., (2009) ApJ, 704, p. 564; Firth, P., Evstigneeva, E.A., Jones, J.B., Drinkwater, M.J., Phillipps, S., Gregg, M.D., (2006) MNRAS, 372, p. 1856; Geller, M.J., Huchra, J.P., (1983) ApJS, 52, p. 61; Girardi, M., Fadda, D., Giuricin, G., Mardirossian, F., Mezzetti, M., Biviano, A., (1996) ApJ, 457, p. 61; Girardi, M., Demarco, R., Rosati, P., Borgani, S., (2005) A&A, 442, p. 29; Gunn, J.E., Gott III, J.R., (1972) ApJ, 176, p. 1; Hou, A., Parker, L.C., Harris, W.E., Wilman, D.J., (2009) ApJ, 702, p. 1199; Iovino, A., (2010) A&A, 509, pp. A40; Katz, N., White, S.D.M., (1993) ApJ, 412, p. 455; Kawata, D., Mulchaey, J.S., (2008) ApJ, 672, pp. L103; Knebe, A., Müller, V., (2000) A&A, 354, p. 761; Lacey, C., Cole, S., (1993) MNRAS, 262, p. 627; Lara-López, M.A., Bongiovanni, A., Cepa, J., Pérez, G.A.M., Sánchez-Portal, M., Castañeda, H.O., Fernández, L.M., Pović, M., (2010) A&A, 519, pp. A31; Larson, R.B., Tinsley, B.M., Caldwell, C.N., (1980) ApJ, 237, p. 692; 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; Mamon, G.A., (2007) The Evolution of Galaxy Groups and of Galaxies Therein, p. 203. , in Saviane I., Ivanov V. D., Borissova J., eds, Springer-Verlag, Berlin, p; Menci, N., Fusco-Femiano, R., (1996) ApJ, 472, p. 46; Moore, B., Katz, N., Lake, G., (1996) ApJ, 457, p. 455; Nelson, L., (1998) J. Quality Technol., 30, p. 298; Peng, Y.-j., (2010) ApJ, 721, p. 193; Pinkney, J., Roettiger, K., Burns, J.O., Bird, C.M., (1996) ApJS, 104, p. 1; Postman, M., Geller, M.J., (1984) ApJ, 281, p. 95; Press, W.H., Schechter, P., (1974) ApJ, 187, p. 425; Quilis, V., Moore, B., Bower, R., (2000) Sci, 288, p. 1617; Ramella, M., (2007) A&A, 470, p. 39; Ribeiro, A.L.B., Lopes, P.A.A., Trevisan, M., (2010) MNRAS, 409, pp. L124; Salim, S., (2007) ApJS, 173, p. 267; Silverman, B.W., (1986) Density Estimation for Statistics and Data Analysis, , Chapman and Hall, London; Solanes, J.M., Salvador-Solé, E., González-Casado, G., (1999) A&A, 343, p. 733; Springel, V., (2005) Nat, 435, p. 629; Springel, V., (2008) MNRAS, 391, p. 1685; Summers, F.J., Davis, M., Evrard, A.E., (1995) ApJ, 454, p. 1; Taylor, J.E., Babul, A., (2004) MNRAS, 348, p. 811; Toomre, A., Toomre, J., (1972) ApJ, 178, p. 623; Tyler, K.D., (2011) ApJ, 738, p. 56; von, d.L.A., Wild, V., Kauffmann, G., White, S.D.M., Weinmann, S., (2010) MNRAS, 404, p. 1231; Weinmann, S.M., van den, B.F.C., Yang, X., Mo, H.J., (2006) MNRAS, 366, p. 2; West, M.J., Bothun, G.D., (1990) ApJ, 350, p. 36; Wetzel, A.R., Tinker, J.L., Conroy, C., (2011), ArXiv e-prints; 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., (2008) ApJ, 680, p. 1009; Wilman, D.J., Oemler, A., Mulchaey, J.S., McGee, S.L., Balogh, M.L., Bower, R.G., (2009) ApJ, 692, p. 298; Wilman, D.J., Zibetti, S., Budavári, T., (2010) MNRAS, 406, p. 1701; Wolf, C., (2009) MNRAS, 393, p. 1302; Yang, X., Mo, H.J., van den, B.F.C., Pasquali, A., Li, C., Barden, M., (2007) ApJ, 671, p. 153; Yee, H.K.C., (2000) ApJS, 129, p. 475; Zabludoff, A.I., Mulchaey, J.S., (1998) ApJ, 496, p. 39; Zabludoff, A.I., Mulchaey, J.S., (1998) ApJ, 498, pp. L5

Keywords

Galaxies: evolution
Galaxies: groups: general
Galaxies: statistics

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10.1111/j.1365-2966.2012.20586.x

https://www.scopus.com/inward/record.uri?eid=2-s2.0-84859573794&doi=10.1111%2fj.1365-2966.2012.20586.x&partnerID=40&md5=9d05545b8a88143026e1217a54dbf23b

Cite this

@article{0535943d863540f494b29ddf8d8e60c9,

title = "Substructure in the most massive GEEC groups: Field-like populations in dynamically active groups",

abstract = "The presence of substructure in galaxy groups and clusters is believed to be a sign of recent galaxy accretion and can be used to probe not only the assembly history of these structures, but also the evolution of their member galaxies. Using the Dressler-Shectman (DS) test, we study substructure in a sample of intermediate-redshift (z∼ 0.4) galaxy groups from the Group Environment and Evolution Collaboration (GEEC) group catalogue. We find that four of the 15 rich GEEC groups, with an average velocity dispersion of ∼525kms -1, are identified as having significant substructure. The identified regions of localized substructure lie on the group outskirts and in some cases appear to be infalling. In a comparison of galaxy properties for the members of groups with and without substructure, we find that the groups with substructure have a significantly higher fraction of blue and star-forming galaxies and a parent colour distribution that resembles that of the field population rather than the overall group population. In addition, we observe correlations between the detection of substructure and other dynamical measures, such as velocity distributions and velocity dispersion profiles. Based on this analysis, we conclude that some galaxy groups contain significant substructure and that these groups have properties and galaxy populations that differ from groups with no detected substructure. These results indicate that the substructure galaxies, which lie preferentially on the group outskirts and could be infalling, do not exhibit signs of environmental effects, since little or no star formation quenching is observed in these systems. {\textcopyright} 2012 The Authors Monthly Notices of the Royal Astronomical Society {\textcopyright} 2012 RAS.",

keywords = "Galaxies: evolution, Galaxies: groups: general, Galaxies: statistics",

author = "A. Hou and L.C. Parker and D.J. Wilman and S.L. Mcgee and W.E. Harris and J.L. Connelly and M.L. Balogh and J.S. Mulchaey and R.G. Bower",

note = "Export Date: 15 August 2017 CODEN: MNRAA Correspondence Address: Hou, A.; Department of Physics and Astronomy, McMaster University, Hamilton ON L8S 4M1, Canada; email: houa2@physics.mcmaster.ca References: Abadi, M.G., Moore, B., Bower, R.G., (1999) MNRAS, 308, p. 947; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., (2011) MNRAS, 412, p. 2303; Barrena, R., Boschin, W., Girardi, M., Spolaor, M., (2007) A&A, 469, p. 861; Beers, T.C., Geller, M.J., Huchra, J.P., (1982) ApJ, 257, p. 23; Bergond, G., Zepf, S.E., Romanowsky, A.J., Sharples, R.M., Rhode, K.L., (2006) A&A, 448, p. 155; Berlind, A.A., (2006) ApJS, 167, p. 1; Bird, C., (1994) ApJ, 422, p. 480; Bird, C.M., (1994) AJ, 107, p. 1637; B{\"o}hringer, H., (2010) A&A, 514, pp. A32; 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; Brough, S., Forbes, D.A., Kilborn, V.A., Couch, W., (2006) MNRAS, 370, p. 1223; Bruzual, G., Charlot, S., (2003) MNRAS, 344, p. 1000; Burgett, W.S., (2004) MNRAS, 352, p. 605; Cameron, E., (2011) PASA, 28, p. 128; 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, 552, p. 427; Charlot, S., Fall, S.M., (2000) ApJ, 539, p. 718; Colless, M., Dunn, A.M., (1996) ApJ, 458, p. 435; D'Agostino, R., Stephens, M., (1986) Goodness-of-fit Techniques, , Marcel Dekker Inc., New York; Diemand, J., Kuhlen, M., Madau, P., Zemp, M., Moore, B., Potter, D., Stadel, J., (2008) Nat, 454, p. 735; Dressler, A., Shectman, S.A., (1988) AJ, 95, p. 985; Dressler, A., (1997) ApJ, 490, p. 577; Efron, B., (1982) The Jackknife, the Bootstrap and Other Resampling Plans, , Society for Industrial and Applied Mathematics, Philadelphia; Eke, V.R., Baugh, C.M., Cole, S., Frenk, C.S., King, H.M., Peacock, J.A., (2005) MNRAS, 362, p. 1233; Finoguenov, A., (2009) ApJ, 704, p. 564; Firth, P., Evstigneeva, E.A., Jones, J.B., Drinkwater, M.J., Phillipps, S., Gregg, M.D., (2006) MNRAS, 372, p. 1856; Geller, M.J., Huchra, J.P., (1983) ApJS, 52, p. 61; Girardi, M., Fadda, D., Giuricin, G., Mardirossian, F., Mezzetti, M., Biviano, A., (1996) ApJ, 457, p. 61; Girardi, M., Demarco, R., Rosati, P., Borgani, S., (2005) A&A, 442, p. 29; Gunn, J.E., Gott III, J.R., (1972) ApJ, 176, p. 1; Hou, A., Parker, L.C., Harris, W.E., Wilman, D.J., (2009) ApJ, 702, p. 1199; Iovino, A., (2010) A&A, 509, pp. A40; Katz, N., White, S.D.M., (1993) ApJ, 412, p. 455; Kawata, D., Mulchaey, J.S., (2008) ApJ, 672, pp. L103; Knebe, A., M{\"u}ller, V., (2000) A&A, 354, p. 761; Lacey, C., Cole, S., (1993) MNRAS, 262, p. 627; Lara-L{\'o}pez, M.A., Bongiovanni, A., Cepa, J., P{\'e}rez, G.A.M., S{\'a}nchez-Portal, M., Casta{\~n}eda, H.O., Fern{\'a}ndez, L.M., Povi{\'c}, M., (2010) A&A, 519, pp. A31; Larson, R.B., Tinsley, B.M., Caldwell, C.N., (1980) ApJ, 237, p. 692; 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; Mamon, G.A., (2007) The Evolution of Galaxy Groups and of Galaxies Therein, p. 203. , in Saviane I., Ivanov V. D., Borissova J., eds, Springer-Verlag, Berlin, p; Menci, N., Fusco-Femiano, R., (1996) ApJ, 472, p. 46; Moore, B., Katz, N., Lake, G., (1996) ApJ, 457, p. 455; Nelson, L., (1998) J. Quality Technol., 30, p. 298; Peng, Y.-j., (2010) ApJ, 721, p. 193; Pinkney, J., Roettiger, K., Burns, J.O., Bird, C.M., (1996) ApJS, 104, p. 1; Postman, M., Geller, M.J., (1984) ApJ, 281, p. 95; Press, W.H., Schechter, P., (1974) ApJ, 187, p. 425; Quilis, V., Moore, B., Bower, R., (2000) Sci, 288, p. 1617; Ramella, M., (2007) A&A, 470, p. 39; Ribeiro, A.L.B., Lopes, P.A.A., Trevisan, M., (2010) MNRAS, 409, pp. L124; Salim, S., (2007) ApJS, 173, p. 267; Silverman, B.W., (1986) Density Estimation for Statistics and Data Analysis, , Chapman and Hall, London; Solanes, J.M., Salvador-Sol{\'e}, E., Gonz{\'a}lez-Casado, G., (1999) A&A, 343, p. 733; Springel, V., (2005) Nat, 435, p. 629; Springel, V., (2008) MNRAS, 391, p. 1685; Summers, F.J., Davis, M., Evrard, A.E., (1995) ApJ, 454, p. 1; Taylor, J.E., Babul, A., (2004) MNRAS, 348, p. 811; Toomre, A., Toomre, J., (1972) ApJ, 178, p. 623; Tyler, K.D., (2011) ApJ, 738, p. 56; von, d.L.A., Wild, V., Kauffmann, G., White, S.D.M., Weinmann, S., (2010) MNRAS, 404, p. 1231; Weinmann, S.M., van den, B.F.C., Yang, X., Mo, H.J., (2006) MNRAS, 366, p. 2; West, M.J., Bothun, G.D., (1990) ApJ, 350, p. 36; Wetzel, A.R., Tinker, J.L., Conroy, C., (2011), ArXiv e-prints; 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., (2008) ApJ, 680, p. 1009; Wilman, D.J., Oemler, A., Mulchaey, J.S., McGee, S.L., Balogh, M.L., Bower, R.G., (2009) ApJ, 692, p. 298; Wilman, D.J., Zibetti, S., Budav{\'a}ri, T., (2010) MNRAS, 406, p. 1701; Wolf, C., (2009) MNRAS, 393, p. 1302; Yang, X., Mo, H.J., van den, B.F.C., Pasquali, A., Li, C., Barden, M., (2007) ApJ, 671, p. 153; Yee, H.K.C., (2000) ApJS, 129, p. 475; Zabludoff, A.I., Mulchaey, J.S., (1998) ApJ, 496, p. 39; Zabludoff, A.I., Mulchaey, J.S., (1998) ApJ, 498, pp. L5",

year = "2012",

doi = "10.1111/j.1365-2966.2012.20586.x",

language = "English",

volume = "421",

pages = "3594--3611",

journal = "Royal Astronomical Society. Monthly Notices",

issn = "0035-8711",

publisher = "SIPRI/Oxford University Press",

number = "4",

}

TY - JOUR

T1 - Substructure in the most massive GEEC groups: Field-like populations in dynamically active groups

AU - Hou, A.

AU - Parker, L.C.

AU - Wilman, D.J.

AU - Mcgee, S.L.

AU - Harris, W.E.

AU - Connelly, J.L.

AU - Balogh, M.L.

AU - Mulchaey, J.S.

AU - Bower, R.G.

N1 - Export Date: 15 August 2017 CODEN: MNRAA Correspondence Address: Hou, A.; Department of Physics and Astronomy, McMaster University, Hamilton ON L8S 4M1, Canada; email: houa2@physics.mcmaster.ca References: Abadi, M.G., Moore, B., Bower, R.G., (1999) MNRAS, 308, p. 947; Balogh, M.L., Navarro, J.F., Morris, S.L., (2000) ApJ, 540, p. 113; Balogh, M.L., (2009) MNRAS, 398, p. 754; Balogh, M.L., (2011) MNRAS, 412, p. 2303; Barrena, R., Boschin, W., Girardi, M., Spolaor, M., (2007) A&A, 469, p. 861; Beers, T.C., Geller, M.J., Huchra, J.P., (1982) ApJ, 257, p. 23; Bergond, G., Zepf, S.E., Romanowsky, A.J., Sharples, R.M., Rhode, K.L., (2006) A&A, 448, p. 155; Berlind, A.A., (2006) ApJS, 167, p. 1; Bird, C., (1994) ApJ, 422, p. 480; Bird, C.M., (1994) AJ, 107, p. 1637; Böhringer, H., (2010) A&A, 514, pp. A32; 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; Brough, S., Forbes, D.A., Kilborn, V.A., Couch, W., (2006) MNRAS, 370, p. 1223; Bruzual, G., Charlot, S., (2003) MNRAS, 344, p. 1000; Burgett, W.S., (2004) MNRAS, 352, p. 605; Cameron, E., (2011) PASA, 28, p. 128; 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, 552, p. 427; Charlot, S., Fall, S.M., (2000) ApJ, 539, p. 718; Colless, M., Dunn, A.M., (1996) ApJ, 458, p. 435; D'Agostino, R., Stephens, M., (1986) Goodness-of-fit Techniques, , Marcel Dekker Inc., New York; Diemand, J., Kuhlen, M., Madau, P., Zemp, M., Moore, B., Potter, D., Stadel, J., (2008) Nat, 454, p. 735; Dressler, A., Shectman, S.A., (1988) AJ, 95, p. 985; Dressler, A., (1997) ApJ, 490, p. 577; Efron, B., (1982) The Jackknife, the Bootstrap and Other Resampling Plans, , Society for Industrial and Applied Mathematics, Philadelphia; Eke, V.R., Baugh, C.M., Cole, S., Frenk, C.S., King, H.M., Peacock, J.A., (2005) MNRAS, 362, p. 1233; Finoguenov, A., (2009) ApJ, 704, p. 564; Firth, P., Evstigneeva, E.A., Jones, J.B., Drinkwater, M.J., Phillipps, S., Gregg, M.D., (2006) MNRAS, 372, p. 1856; Geller, M.J., Huchra, J.P., (1983) ApJS, 52, p. 61; Girardi, M., Fadda, D., Giuricin, G., Mardirossian, F., Mezzetti, M., Biviano, A., (1996) ApJ, 457, p. 61; Girardi, M., Demarco, R., Rosati, P., Borgani, S., (2005) A&A, 442, p. 29; Gunn, J.E., Gott III, J.R., (1972) ApJ, 176, p. 1; Hou, A., Parker, L.C., Harris, W.E., Wilman, D.J., (2009) ApJ, 702, p. 1199; Iovino, A., (2010) A&A, 509, pp. A40; Katz, N., White, S.D.M., (1993) ApJ, 412, p. 455; Kawata, D., Mulchaey, J.S., (2008) ApJ, 672, pp. L103; Knebe, A., Müller, V., (2000) A&A, 354, p. 761; Lacey, C., Cole, S., (1993) MNRAS, 262, p. 627; Lara-López, M.A., Bongiovanni, A., Cepa, J., Pérez, G.A.M., Sánchez-Portal, M., Castañeda, H.O., Fernández, L.M., Pović, M., (2010) A&A, 519, pp. A31; Larson, R.B., Tinsley, B.M., Caldwell, C.N., (1980) ApJ, 237, p. 692; 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; Mamon, G.A., (2007) The Evolution of Galaxy Groups and of Galaxies Therein, p. 203. , in Saviane I., Ivanov V. D., Borissova J., eds, Springer-Verlag, Berlin, p; Menci, N., Fusco-Femiano, R., (1996) ApJ, 472, p. 46; Moore, B., Katz, N., Lake, G., (1996) ApJ, 457, p. 455; Nelson, L., (1998) J. 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PY - 2012

Y1 - 2012

N2 - The presence of substructure in galaxy groups and clusters is believed to be a sign of recent galaxy accretion and can be used to probe not only the assembly history of these structures, but also the evolution of their member galaxies. Using the Dressler-Shectman (DS) test, we study substructure in a sample of intermediate-redshift (z∼ 0.4) galaxy groups from the Group Environment and Evolution Collaboration (GEEC) group catalogue. We find that four of the 15 rich GEEC groups, with an average velocity dispersion of ∼525kms -1, are identified as having significant substructure. The identified regions of localized substructure lie on the group outskirts and in some cases appear to be infalling. In a comparison of galaxy properties for the members of groups with and without substructure, we find that the groups with substructure have a significantly higher fraction of blue and star-forming galaxies and a parent colour distribution that resembles that of the field population rather than the overall group population. In addition, we observe correlations between the detection of substructure and other dynamical measures, such as velocity distributions and velocity dispersion profiles. Based on this analysis, we conclude that some galaxy groups contain significant substructure and that these groups have properties and galaxy populations that differ from groups with no detected substructure. These results indicate that the substructure galaxies, which lie preferentially on the group outskirts and could be infalling, do not exhibit signs of environmental effects, since little or no star formation quenching is observed in these systems. © 2012 The Authors Monthly Notices of the Royal Astronomical Society © 2012 RAS.

AB - The presence of substructure in galaxy groups and clusters is believed to be a sign of recent galaxy accretion and can be used to probe not only the assembly history of these structures, but also the evolution of their member galaxies. Using the Dressler-Shectman (DS) test, we study substructure in a sample of intermediate-redshift (z∼ 0.4) galaxy groups from the Group Environment and Evolution Collaboration (GEEC) group catalogue. We find that four of the 15 rich GEEC groups, with an average velocity dispersion of ∼525kms -1, are identified as having significant substructure. The identified regions of localized substructure lie on the group outskirts and in some cases appear to be infalling. In a comparison of galaxy properties for the members of groups with and without substructure, we find that the groups with substructure have a significantly higher fraction of blue and star-forming galaxies and a parent colour distribution that resembles that of the field population rather than the overall group population. In addition, we observe correlations between the detection of substructure and other dynamical measures, such as velocity distributions and velocity dispersion profiles. Based on this analysis, we conclude that some galaxy groups contain significant substructure and that these groups have properties and galaxy populations that differ from groups with no detected substructure. These results indicate that the substructure galaxies, which lie preferentially on the group outskirts and could be infalling, do not exhibit signs of environmental effects, since little or no star formation quenching is observed in these systems. © 2012 The Authors Monthly Notices of the Royal Astronomical Society © 2012 RAS.

KW - Galaxies: evolution

KW - Galaxies: groups: general

KW - Galaxies: statistics

U2 - 10.1111/j.1365-2966.2012.20586.x

DO - 10.1111/j.1365-2966.2012.20586.x

M3 - Article

SN - 0035-8711

VL - 421

SP - 3594

EP - 3611

JO - Royal Astronomical Society. Monthly Notices

JF - Royal Astronomical Society. Monthly Notices

IS - 4

ER -

Substructure in the most massive GEEC groups: Field-like populations in dynamically active groups

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