Galaxy And Mass Assembly (GAMA): gas fuelling of spiral galaxies in the local Universe I. The effect of the group environment on star formation in spiral galaxies

M. W. Grootes; R. J. Tuffs; C. C. Popescu; P. Norberg; A. S. G. Robotham; J. Liske; E. Andrae; I. K. Baldry; M. Gunawardhana; L. S. Kelvin; B. F. Madore; M. Seibert; E. N. Taylor; M. Alpaslan; M. J. I. Brown; M. E. Cluver; S. P. Driver; J. Bland-Hawthorn; B. W. Holwerda; A. M. Hopkins; A. R. Lopez-Sanchez; J. Loveday; M. Rushton

doi:10.3847/1538-3881/153/3/111

Galaxy And Mass Assembly (GAMA): gas fuelling of spiral galaxies in the local Universe I. The effect of the group environment on star formation in spiral galaxies

M. W. Grootes, R. J. Tuffs, C. C. Popescu, P. Norberg, A. S. G. Robotham, J. Liske, E. Andrae, I. K. Baldry, M. Gunawardhana, L. S. Kelvin, B. F. Madore, M. Seibert, E. N. Taylor, M. Alpaslan, M. J. I. Brown, M. E. Cluver, S. P. Driver, J. Bland-Hawthorn, B. W. Holwerda, A. M. HopkinsA. R. Lopez-Sanchez, J. Loveday, M. Rushton

School of Physics and Astronomy

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

Abstract

We quantify the effect of the galaxy group environment (for group masses of 10^12.5–10^14.0 M ⊙) on the current star formation rate (SFR) of a pure, morphologically selected sample of disk-dominated (i.e., late-type spiral) galaxies with redshift ≤0.13. The sample embraces a full representation of quiescent and star-forming disks with stellar mass M * ≥ 10^9.5 M ⊙. We focus on the effects on SFR of interactions between grouped galaxies and the putative intrahalo medium (IHM) of their host group dark matter halos, isolating these effects from those induced through galaxy–galaxy interactions, and utilizing a radiation transfer analysis to remove the inclination dependence of derived SFRs. The dependence of SFR on M * is controlled for by measuring offsets Δlog(ψ *) of grouped galaxies about a single power-law relation in specific SFR, ψ* ∝ M*^{-0.45± 0.01}, exhibited by non-grouped "field" galaxies in the sample. While a small minority of the group satellites are strongly quenched, the group centrals and a large majority of satellites exhibit levels of ψ * statistically indistinguishable from their field counterparts, for all M *, albeit with a higher scatter of 0.44 dex about the field reference relation (versus 0.27 dex for the field). Modeling the distributions in Δlog(ψ *), we find that (i) after infall into groups, disk-dominated galaxies continue to be characterized by a similar rapid cycling of gas into and out of their interstellar medium shown prior to infall, with inflows and outflows of ~1.5–5 x SFR and ~1–4 x SFR, respectively; and (ii) the independence of the continuity of these gas flow cycles on M * appears inconsistent with the required fueling being sourced from gas in the circumgalactic medium on scales of ~100 kpc. Instead, our data favor ongoing fueling of satellites from the IHM of the host group halo on ~Mpc scales, i.e., from gas not initially associated with the galaxies upon infall. Consequently, the color–density relation of the galaxy population as a whole would appear to be primarily due to a change in the mix of disk- and spheroid-dominated morphologies in the denser group environment compared to the field, rather than to a reduced propensity of the IHM in higher-mass structures to cool and accrete onto galaxies. We also suggest that the required substantial accretion of IHM gas by satellite disk-dominated galaxies will lead to a progressive reduction in the specific angular momentum of these systems, thereby representing an efficient secular mechanism to transform morphology from star-forming disk-dominated types to more passive spheroid-dominated types.

Original language	English
Article number	111
Number of pages	49
Journal	Astrophysical Journal
Volume	153
Issue number	3
Early online date	15 Feb 2017
DOIs	https://doi.org/10.3847/1538-3881/153/3/111
Publication status	Published - Mar 2017

Keywords

Galaxies: fundamental parameters
Galaxies: groups: general
Galaxies: ISM
Galaxies: spiral
Intergalactic medium
Surveys

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10.3847/1538-3881/153/3/111

Grootes_2017_AJ_153_111
© 2017, American Astronomical Society. This work has been made available online in accordance with the publisher’s policies. This is the final published version of the work, which was originally published at https://doi.org/10.3847/1538-3881/153/3/111
Final published version, 5.54 MB

http://arxiv.org/abs/1612.07322v1

GAMA Panchromatic Data Release
Driver, S. P. (Creator), Wright, A. H. (Creator), Andrews, S. K. (Creator), Davies, L. J. (Creator), Kafle, P. R. (Creator), Lange, R. (Creator), Moffett, A. J. (Creator), Mannering, E. (Creator), Robotham, A. S. G. (Creator), Vinsen, K. (Creator), Andrae, E. (Creator), Baldry, I. K. (Creator), Bauer, A. E. (Creator), Bamford, S. P. (Creator), Bland-Hawthorn, J. (Creator), Bourne, N. (Creator), Brough, S. (Creator), Brown, M. J. I. (Creator), Cluver, M. E. (Creator), Croom, S. (Creator), Colless, M. (Creator), Conselice, C. J. (Creator), da Cunha (Elisabete da Cunha, E. (Creator), De Propris, R. (Creator), Drinkwater, M. (Creator), Dunne, L. (Creator), Eales, S. (Creator), Edge, A. (Creator), Frenk, C. (Creator), Graham, A. W. (Creator), Grootes, M. (Creator), Holwerda, B. W. (Creator), Hopkins, A. M. (Creator), Ibar, E. (Creator), van Kampen, E. (Creator), Kelvin, L. S. (Creator), Jarrett, T. (Creator), Jones, D. H. (Creator), Lara-Lopez, M. A. (Creator), Liske, J. (Creator), Lopez-Sanchez, A. R. (Creator), Loveday, J. (Creator), Maddox, S. J. (Creator), Madore, B. (Creator), Mahajan (Smriti Mahajan), S. (Creator), Meyer, M. (Creator), Norberg, P. (Creator), Penny, S. J. (Creator), Phillipps, S. (Creator), Popescu, C. (Creator), Tuffs, R. J. (Creator), Peacock, J. A. (Creator), Pimbblet, K. A. (Creator), Prescott, M. (Creator), Rowlands, K. E. (Creator), Sansom, A. E. (Creator), Seibert, M. (Creator), Smith, M. (Creator), Alpaslan, M. (Creator), Sutherland, W. J. (Creator), Taylor, E. N. (Creator), Valiante, E. (Creator), Vazquez-Mata, J. A. (Creator), Wang, L. (Creator), Wilkins, S. M. (Creator) & Williams, R. (Creator), International Centre for Radio Astronomy Research , 1 Feb 2016
http://cutout.icrar.org/panchromaticDR.php
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Grootes, M. W., Tuffs, R. J., Popescu, C. C., Norberg, P., Robotham, A. S. G., Liske, J., Andrae, E., Baldry, I. K., Gunawardhana, M., Kelvin, L. S., Madore, B. F., Seibert, M., Taylor, E. N., Alpaslan, M., Brown, M. J. I., Cluver, M. E., Driver, S. P., Bland-Hawthorn, J., Holwerda, B. W., ... Rushton, M. (2017). Galaxy And Mass Assembly (GAMA): gas fuelling of spiral galaxies in the local Universe I. The effect of the group environment on star formation in spiral galaxies. Astrophysical Journal, 153(3), Article 111. https://doi.org/10.3847/1538-3881/153/3/111

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title = "Galaxy And Mass Assembly (GAMA): gas fuelling of spiral galaxies in the local Universe I. The effect of the group environment on star formation in spiral galaxies",

abstract = "We quantify the effect of the galaxy group environment (for group masses of 1012.5–1014.0 M ⊙) on the current star formation rate (SFR) of a pure, morphologically selected sample of disk-dominated (i.e., late-type spiral) galaxies with redshift ≤0.13. The sample embraces a full representation of quiescent and star-forming disks with stellar mass M * ≥ 109.5 M ⊙. We focus on the effects on SFR of interactions between grouped galaxies and the putative intrahalo medium (IHM) of their host group dark matter halos, isolating these effects from those induced through galaxy–galaxy interactions, and utilizing a radiation transfer analysis to remove the inclination dependence of derived SFRs. The dependence of SFR on M * is controlled for by measuring offsets Δlog(ψ *) of grouped galaxies about a single power-law relation in specific SFR, ψ* ∝ M*-0.45± 0.01, exhibited by non-grouped {"}field{"} galaxies in the sample. While a small minority of the group satellites are strongly quenched, the group centrals and a large majority of satellites exhibit levels of ψ * statistically indistinguishable from their field counterparts, for all M *, albeit with a higher scatter of 0.44 dex about the field reference relation (versus 0.27 dex for the field). Modeling the distributions in Δlog(ψ *), we find that (i) after infall into groups, disk-dominated galaxies continue to be characterized by a similar rapid cycling of gas into and out of their interstellar medium shown prior to infall, with inflows and outflows of ~1.5–5 x SFR and ~1–4 x SFR, respectively; and (ii) the independence of the continuity of these gas flow cycles on M * appears inconsistent with the required fueling being sourced from gas in the circumgalactic medium on scales of ~100 kpc. Instead, our data favor ongoing fueling of satellites from the IHM of the host group halo on ~Mpc scales, i.e., from gas not initially associated with the galaxies upon infall. Consequently, the color–density relation of the galaxy population as a whole would appear to be primarily due to a change in the mix of disk- and spheroid-dominated morphologies in the denser group environment compared to the field, rather than to a reduced propensity of the IHM in higher-mass structures to cool and accrete onto galaxies. We also suggest that the required substantial accretion of IHM gas by satellite disk-dominated galaxies will lead to a progressive reduction in the specific angular momentum of these systems, thereby representing an efficient secular mechanism to transform morphology from star-forming disk-dominated types to more passive spheroid-dominated types.",

keywords = "Galaxies: fundamental parameters, Galaxies: groups: general, Galaxies: ISM, Galaxies: spiral, Intergalactic medium, Surveys",

author = "Grootes, {M. W.} and Tuffs, {R. J.} and Popescu, {C. C.} and P. Norberg and Robotham, {A. S. G.} and J. Liske and E. Andrae and Baldry, {I. K.} and M. Gunawardhana and Kelvin, {L. S.} and Madore, {B. F.} and M. Seibert and Taylor, {E. N.} and M. Alpaslan and Brown, {M. J. I.} and Cluver, {M. E.} and Driver, {S. P.} and J. Bland-Hawthorn and Holwerda, {B. W.} and Hopkins, {A. M.} and Lopez-Sanchez, {A. R.} and J. Loveday and M. Rushton",

year = "2017",

month = mar,

doi = "10.3847/1538-3881/153/3/111",

language = "English",

volume = "153",

journal = "Astrophysical Journal",

issn = "0004-637X",

publisher = "American Astronomical Society",

number = "3",

}

Grootes, MW, Tuffs, RJ, Popescu, CC, Norberg, P, Robotham, ASG, Liske, J, Andrae, E, Baldry, IK, Gunawardhana, M, Kelvin, LS, Madore, BF, Seibert, M, Taylor, EN, Alpaslan, M, Brown, MJI, Cluver, ME, Driver, SP, Bland-Hawthorn, J, Holwerda, BW, Hopkins, AM, Lopez-Sanchez, AR, Loveday, J & Rushton, M 2017, 'Galaxy And Mass Assembly (GAMA): gas fuelling of spiral galaxies in the local Universe I. The effect of the group environment on star formation in spiral galaxies', Astrophysical Journal, vol. 153, no. 3, 111. https://doi.org/10.3847/1538-3881/153/3/111

TY - JOUR

T1 - Galaxy And Mass Assembly (GAMA)

T2 - gas fuelling of spiral galaxies in the local Universe I. The effect of the group environment on star formation in spiral galaxies

AU - Grootes, M. W.

AU - Tuffs, R. J.

AU - Popescu, C. C.

AU - Norberg, P.

AU - Robotham, A. S. G.

AU - Liske, J.

AU - Andrae, E.

AU - Baldry, I. K.

AU - Gunawardhana, M.

AU - Kelvin, L. S.

AU - Madore, B. F.

AU - Seibert, M.

AU - Taylor, E. N.

AU - Alpaslan, M.

AU - Brown, M. J. I.

AU - Cluver, M. E.

AU - Driver, S. P.

AU - Bland-Hawthorn, J.

AU - Holwerda, B. W.

AU - Hopkins, A. M.

AU - Lopez-Sanchez, A. R.

AU - Loveday, J.

AU - Rushton, M.

PY - 2017/3

Y1 - 2017/3

N2 - We quantify the effect of the galaxy group environment (for group masses of 1012.5–1014.0 M ⊙) on the current star formation rate (SFR) of a pure, morphologically selected sample of disk-dominated (i.e., late-type spiral) galaxies with redshift ≤0.13. The sample embraces a full representation of quiescent and star-forming disks with stellar mass M * ≥ 109.5 M ⊙. We focus on the effects on SFR of interactions between grouped galaxies and the putative intrahalo medium (IHM) of their host group dark matter halos, isolating these effects from those induced through galaxy–galaxy interactions, and utilizing a radiation transfer analysis to remove the inclination dependence of derived SFRs. The dependence of SFR on M * is controlled for by measuring offsets Δlog(ψ *) of grouped galaxies about a single power-law relation in specific SFR, ψ* ∝ M*-0.45± 0.01, exhibited by non-grouped "field" galaxies in the sample. While a small minority of the group satellites are strongly quenched, the group centrals and a large majority of satellites exhibit levels of ψ * statistically indistinguishable from their field counterparts, for all M *, albeit with a higher scatter of 0.44 dex about the field reference relation (versus 0.27 dex for the field). Modeling the distributions in Δlog(ψ *), we find that (i) after infall into groups, disk-dominated galaxies continue to be characterized by a similar rapid cycling of gas into and out of their interstellar medium shown prior to infall, with inflows and outflows of ~1.5–5 x SFR and ~1–4 x SFR, respectively; and (ii) the independence of the continuity of these gas flow cycles on M * appears inconsistent with the required fueling being sourced from gas in the circumgalactic medium on scales of ~100 kpc. Instead, our data favor ongoing fueling of satellites from the IHM of the host group halo on ~Mpc scales, i.e., from gas not initially associated with the galaxies upon infall. Consequently, the color–density relation of the galaxy population as a whole would appear to be primarily due to a change in the mix of disk- and spheroid-dominated morphologies in the denser group environment compared to the field, rather than to a reduced propensity of the IHM in higher-mass structures to cool and accrete onto galaxies. We also suggest that the required substantial accretion of IHM gas by satellite disk-dominated galaxies will lead to a progressive reduction in the specific angular momentum of these systems, thereby representing an efficient secular mechanism to transform morphology from star-forming disk-dominated types to more passive spheroid-dominated types.

AB - We quantify the effect of the galaxy group environment (for group masses of 1012.5–1014.0 M ⊙) on the current star formation rate (SFR) of a pure, morphologically selected sample of disk-dominated (i.e., late-type spiral) galaxies with redshift ≤0.13. The sample embraces a full representation of quiescent and star-forming disks with stellar mass M * ≥ 109.5 M ⊙. We focus on the effects on SFR of interactions between grouped galaxies and the putative intrahalo medium (IHM) of their host group dark matter halos, isolating these effects from those induced through galaxy–galaxy interactions, and utilizing a radiation transfer analysis to remove the inclination dependence of derived SFRs. The dependence of SFR on M * is controlled for by measuring offsets Δlog(ψ *) of grouped galaxies about a single power-law relation in specific SFR, ψ* ∝ M*-0.45± 0.01, exhibited by non-grouped "field" galaxies in the sample. While a small minority of the group satellites are strongly quenched, the group centrals and a large majority of satellites exhibit levels of ψ * statistically indistinguishable from their field counterparts, for all M *, albeit with a higher scatter of 0.44 dex about the field reference relation (versus 0.27 dex for the field). Modeling the distributions in Δlog(ψ *), we find that (i) after infall into groups, disk-dominated galaxies continue to be characterized by a similar rapid cycling of gas into and out of their interstellar medium shown prior to infall, with inflows and outflows of ~1.5–5 x SFR and ~1–4 x SFR, respectively; and (ii) the independence of the continuity of these gas flow cycles on M * appears inconsistent with the required fueling being sourced from gas in the circumgalactic medium on scales of ~100 kpc. Instead, our data favor ongoing fueling of satellites from the IHM of the host group halo on ~Mpc scales, i.e., from gas not initially associated with the galaxies upon infall. Consequently, the color–density relation of the galaxy population as a whole would appear to be primarily due to a change in the mix of disk- and spheroid-dominated morphologies in the denser group environment compared to the field, rather than to a reduced propensity of the IHM in higher-mass structures to cool and accrete onto galaxies. We also suggest that the required substantial accretion of IHM gas by satellite disk-dominated galaxies will lead to a progressive reduction in the specific angular momentum of these systems, thereby representing an efficient secular mechanism to transform morphology from star-forming disk-dominated types to more passive spheroid-dominated types.

KW - Galaxies: fundamental parameters

KW - Galaxies: groups: general

KW - Galaxies: ISM

KW - Galaxies: spiral

KW - Intergalactic medium

KW - Surveys

U2 - 10.3847/1538-3881/153/3/111

DO - 10.3847/1538-3881/153/3/111

M3 - Article

SN - 0004-637X

VL - 153

JO - Astrophysical Journal

JF - Astrophysical Journal

IS - 3

M1 - 111

ER -

Galaxy And Mass Assembly (GAMA): gas fuelling of spiral galaxies in the local Universe I. The effect of the group environment on star formation in spiral galaxies

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GAMA Panchromatic Data Release

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