Cold-mode accretion: Driving the fundamental mass-metallicity relation at z ∼ 2

Glenn G. Kacprzak; Freeke Van De Voort; Karl Glazebrook; Kim Vy H. Tran; Tiantian Yuan; Themiya Nanayakkara; Rebecca J. Allen; Leo Alcorn; Michael Cowley; Ivo Labbé; Lee Spitler; Caroline Straatman; Adam Tomczak

doi:10.3847/2041-8205/826/1/L11

Cold-mode accretion: Driving the fundamental mass-metallicity relation at z ∼ 2

Glenn G. Kacprzak, Freeke Van De Voort, Karl Glazebrook, Kim Vy H. Tran, Tiantian Yuan, Themiya Nanayakkara, Rebecca J. Allen, Leo Alcorn, Michael Cowley, Ivo Labbé, Lee Spitler, Caroline Straatman, Adam Tomczak

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Abstract

We investigate the star formation rate (SFR) dependence on the stellar mass and gas-phase metallicity relation at z = 2 with MOSFIRE/Keck as part of the ZFIRE survey. We have identified 117 galaxies (1.98 ≤ z ≤ 2.56), with 8.9 ≤ log(M/M _o) ≤ 11.0, for which we can measure gas-phase metallicities. For the first time, we show a discernible difference between the mass-metallicity relation, using individual galaxies, when dividing the sample by low (<10 M _o yr^-1) and high (>10 M _o yr^-1) SFRs. At fixed mass, low star-forming galaxies tend to have higher metallicity than high star-forming galaxies. Using a few basic assumptions, we further show that the gas masses and metallicities required to produce the fundamental mass-metallicity relation and its intrinsic scatter are consistent with cold-mode accretion predictions obtained from the OWLS hydrodynamical simulations. Our results from both simulations and observations are suggestive that cold-mode accretion is responsible for the fundamental mass-metallicity relation at z = 2 and it demonstrates the direct relationship between cosmological accretion and the fundamental properties of galaxies.

Original language	English
Article number	L11
Journal	Astrophysical Journal Letters
Volume	826
Issue number	1
DOIs	https://doi.org/10.3847/2041-8205/826/1/L11
Publication status	Published - 20 Jul 2016

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Kacprzak, G. G., Van De Voort, F., Glazebrook, K., Tran, K. V. H., Yuan, T., Nanayakkara, T., Allen, R. J., Alcorn, L., Cowley, M., Labbé, I., Spitler, L., Straatman, C., & Tomczak, A. (2016). Cold-mode accretion: Driving the fundamental mass-metallicity relation at z ∼ 2. Astrophysical Journal Letters, 826(1), Article L11. https://doi.org/10.3847/2041-8205/826/1/L11

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title = "Cold-mode accretion: Driving the fundamental mass-metallicity relation at z ∼ 2",

abstract = "We investigate the star formation rate (SFR) dependence on the stellar mass and gas-phase metallicity relation at z = 2 with MOSFIRE/Keck as part of the ZFIRE survey. We have identified 117 galaxies (1.98 ≤ z ≤ 2.56), with 8.9 ≤ log(M/M o) ≤ 11.0, for which we can measure gas-phase metallicities. For the first time, we show a discernible difference between the mass-metallicity relation, using individual galaxies, when dividing the sample by low (<10 M o yr-1) and high (>10 M o yr-1) SFRs. At fixed mass, low star-forming galaxies tend to have higher metallicity than high star-forming galaxies. Using a few basic assumptions, we further show that the gas masses and metallicities required to produce the fundamental mass-metallicity relation and its intrinsic scatter are consistent with cold-mode accretion predictions obtained from the OWLS hydrodynamical simulations. Our results from both simulations and observations are suggestive that cold-mode accretion is responsible for the fundamental mass-metallicity relation at z = 2 and it demonstrates the direct relationship between cosmological accretion and the fundamental properties of galaxies.",

keywords = "cosmology: observations, galaxies: abundances, galaxies: evolution, galaxies: fundamental parameters, galaxies: high-redshift, intergalactic medium",

author = "Kacprzak, {Glenn G.} and {Van De Voort}, Freeke and Karl Glazebrook and Tran, {Kim Vy H.} and Tiantian Yuan and Themiya Nanayakkara and Allen, {Rebecca J.} and Leo Alcorn and Michael Cowley and Ivo Labb{\'e} and Lee Spitler and Caroline Straatman and Adam Tomczak",

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T1 - Cold-mode accretion

T2 - Driving the fundamental mass-metallicity relation at z ∼ 2

AU - Kacprzak, Glenn G.

AU - Van De Voort, Freeke

AU - Glazebrook, Karl

AU - Tran, Kim Vy H.

AU - Yuan, Tiantian

AU - Nanayakkara, Themiya

AU - Allen, Rebecca J.

AU - Alcorn, Leo

AU - Cowley, Michael

AU - Labbé, Ivo

AU - Spitler, Lee

AU - Straatman, Caroline

AU - Tomczak, Adam

PY - 2016/7/20

Y1 - 2016/7/20

N2 - We investigate the star formation rate (SFR) dependence on the stellar mass and gas-phase metallicity relation at z = 2 with MOSFIRE/Keck as part of the ZFIRE survey. We have identified 117 galaxies (1.98 ≤ z ≤ 2.56), with 8.9 ≤ log(M/M o) ≤ 11.0, for which we can measure gas-phase metallicities. For the first time, we show a discernible difference between the mass-metallicity relation, using individual galaxies, when dividing the sample by low (<10 M o yr-1) and high (>10 M o yr-1) SFRs. At fixed mass, low star-forming galaxies tend to have higher metallicity than high star-forming galaxies. Using a few basic assumptions, we further show that the gas masses and metallicities required to produce the fundamental mass-metallicity relation and its intrinsic scatter are consistent with cold-mode accretion predictions obtained from the OWLS hydrodynamical simulations. Our results from both simulations and observations are suggestive that cold-mode accretion is responsible for the fundamental mass-metallicity relation at z = 2 and it demonstrates the direct relationship between cosmological accretion and the fundamental properties of galaxies.

AB - We investigate the star formation rate (SFR) dependence on the stellar mass and gas-phase metallicity relation at z = 2 with MOSFIRE/Keck as part of the ZFIRE survey. We have identified 117 galaxies (1.98 ≤ z ≤ 2.56), with 8.9 ≤ log(M/M o) ≤ 11.0, for which we can measure gas-phase metallicities. For the first time, we show a discernible difference between the mass-metallicity relation, using individual galaxies, when dividing the sample by low (<10 M o yr-1) and high (>10 M o yr-1) SFRs. At fixed mass, low star-forming galaxies tend to have higher metallicity than high star-forming galaxies. Using a few basic assumptions, we further show that the gas masses and metallicities required to produce the fundamental mass-metallicity relation and its intrinsic scatter are consistent with cold-mode accretion predictions obtained from the OWLS hydrodynamical simulations. Our results from both simulations and observations are suggestive that cold-mode accretion is responsible for the fundamental mass-metallicity relation at z = 2 and it demonstrates the direct relationship between cosmological accretion and the fundamental properties of galaxies.

KW - cosmology: observations

KW - galaxies: abundances

KW - galaxies: evolution

KW - galaxies: fundamental parameters

KW - galaxies: high-redshift

KW - intergalactic medium

UR - http://www.scopus.com/inward/record.url?scp=84979247387&partnerID=8YFLogxK

U2 - 10.3847/2041-8205/826/1/L11

DO - 10.3847/2041-8205/826/1/L11

M3 - Article

SN - 2041-8205

VL - 826

JO - Astrophysical Journal Letters

JF - Astrophysical Journal Letters

IS - 1

M1 - L11

ER -

Cold-mode accretion: Driving the fundamental mass-metallicity relation at z ∼ 2

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