IMAGES: III. The evolution of the near-infrared Tully-Fisher relation over the last 6 Gyr

M. Puech; H. Flores; F. Hammer; Y. Yang; B. Neichel; M. Lehnert; L. Chemin; N. Nesvadba; B. Epinat; P. Amram; C. Balkowski; C. Cesarsky; H. Dannerbauer; S. Di Serego Alighieri; I. Fuentes-Carrera; B. Guiderdoni; A. Kembhavi; Y. C. Liang; G. Östlin; L. Pozzetti; C. D. Ravikumar; A. Rawat; D. Vergani; A. Vernet; H. Wozniak

doi:10.1051/0004-6361:20079313

IMAGES: III. The evolution of the near-infrared Tully-Fisher relation over the last 6 Gyr

M. Puech, H. Flores, F. Hammer, Y. Yang, B. Neichel, M. Lehnert, L. Chemin, N. Nesvadba, B. Epinat, P. Amram, C. Balkowski, C. Cesarsky, H. Dannerbauer, S. Di Serego Alighieri, I. Fuentes-Carrera, B. Guiderdoni, A. Kembhavi, Y. C. Liang, G. Östlin, L. PozzettiC. D. Ravikumar, A. Rawat, D. Vergani, A. Vernet, H. Wozniak

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Abstract

Using the multi-integral field spectrograph GIRAFFE at VLT, we have derived the K-band Tully-Fisher relation (TFR) at z ≈ 0.6 for a representative sample of 65 galaxies with emission lines (W0(OII) ≈ 15 A). We confirm that the scatter in the z ≈ 0.6 TFR is caused by galaxies with anomalous kinematics, and find a positive and strong correlation between the complexity of the kinematics and the scatter that they contribute to the TFR. Considering only relaxed-rotating disks, the scatter, and possibly also the slope, of the TFR, do not appear to evolve with redshift. We detect an evolution of the K-band TFR zero point between z ≈ 0.6 and z = 0, which, if interpreted as an evolution of the K-band luminosity of rotating disks, would imply that a brightening of 0.66 ± 0.14 mag occurs between z ≈ 0.6 and z = 0. Any disagreement with the results of Flores et al. (2006, A&A, 455, 107) are attributed to both an improvement of the local TFR and the more detailed accurate measurement of the rotation velocities in the distant sample. Most of the uncertainty can be explained by the relatively coarse spatial-resolution of the kinematical data. Because most rotating disks at z ≈ 0.6 are unlikely to experience further merging events, one may assume that their rotational velocity, which is taken as a proxy of the total mass, does not evolve dramatically. If true, our result implies that rotating disks observed at z ≈ 0.6 are rapidly transforming their gas into stars, to be able to double their stellar masses and be observed on the TFR at z = 0. The rotating disks observed are indeed emission-line galaxies that are either starbursts or LIRGs, which implies that they are forming stars at a high rate. Thus, a significant fraction of the rotating disks are forming the bulk of their stars within 6 to 8 Gyr, in good agreement with former studies of the evolution of the mass-metallicity relationship.

Original language	English
Pages (from-to)	173-187
Number of pages	15
Journal	Astronomy and Astrophysics
Volume	484
Issue number	1
DOIs	https://doi.org/10.1051/0004-6361:20079313
State	Published - Jun 2008
Externally published	Yes

Keywords

Galaxies: evolution
Galaxies: general
Galaxies: high-redshift
Galaxies: interactions
Galaxies: kinematics and dynamics
Galaxies: spiral

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10.1051/0004-6361:20079313

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Puech, M., Flores, H., Hammer, F., Yang, Y., Neichel, B., Lehnert, M., Chemin, L., Nesvadba, N., Epinat, B., Amram, P., Balkowski, C., Cesarsky, C., Dannerbauer, H., Di Serego Alighieri, S., Fuentes-Carrera, I., Guiderdoni, B., Kembhavi, A., Liang, Y. C., Östlin, G., ... Wozniak, H. (2008). IMAGES: III. The evolution of the near-infrared Tully-Fisher relation over the last 6 Gyr. Astronomy and Astrophysics, 484(1), 173-187. https://doi.org/10.1051/0004-6361:20079313

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title = "IMAGES: III. The evolution of the near-infrared Tully-Fisher relation over the last 6 Gyr",

abstract = "Using the multi-integral field spectrograph GIRAFFE at VLT, we have derived the K-band Tully-Fisher relation (TFR) at z ≈ 0.6 for a representative sample of 65 galaxies with emission lines (W0(OII) ≈ 15 A). We confirm that the scatter in the z ≈ 0.6 TFR is caused by galaxies with anomalous kinematics, and find a positive and strong correlation between the complexity of the kinematics and the scatter that they contribute to the TFR. Considering only relaxed-rotating disks, the scatter, and possibly also the slope, of the TFR, do not appear to evolve with redshift. We detect an evolution of the K-band TFR zero point between z ≈ 0.6 and z = 0, which, if interpreted as an evolution of the K-band luminosity of rotating disks, would imply that a brightening of 0.66 ± 0.14 mag occurs between z ≈ 0.6 and z = 0. Any disagreement with the results of Flores et al. (2006, A&A, 455, 107) are attributed to both an improvement of the local TFR and the more detailed accurate measurement of the rotation velocities in the distant sample. Most of the uncertainty can be explained by the relatively coarse spatial-resolution of the kinematical data. Because most rotating disks at z ≈ 0.6 are unlikely to experience further merging events, one may assume that their rotational velocity, which is taken as a proxy of the total mass, does not evolve dramatically. If true, our result implies that rotating disks observed at z ≈ 0.6 are rapidly transforming their gas into stars, to be able to double their stellar masses and be observed on the TFR at z = 0. The rotating disks observed are indeed emission-line galaxies that are either starbursts or LIRGs, which implies that they are forming stars at a high rate. Thus, a significant fraction of the rotating disks are forming the bulk of their stars within 6 to 8 Gyr, in good agreement with former studies of the evolution of the mass-metallicity relationship.",

keywords = "Galaxies: evolution, Galaxies: general, Galaxies: high-redshift, Galaxies: interactions, Galaxies: kinematics and dynamics, Galaxies: spiral",

author = "M. Puech and H. Flores and F. Hammer and Y. Yang and B. Neichel and M. Lehnert and L. Chemin and N. Nesvadba and B. Epinat and P. Amram and C. Balkowski and C. Cesarsky and H. Dannerbauer and {Di Serego Alighieri}, S. and I. Fuentes-Carrera and B. Guiderdoni and A. Kembhavi and Liang, {Y. C.} and G. {\"O}stlin and L. Pozzetti and Ravikumar, {C. D.} and A. Rawat and D. Vergani and A. Vernet and H. Wozniak",

year = "2008",

month = jun,

doi = "10.1051/0004-6361:20079313",

language = "Ingl{\'e}s",

volume = "484",

pages = "173--187",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

number = "1",

}

Puech, M, Flores, H, Hammer, F, Yang, Y, Neichel, B, Lehnert, M, Chemin, L, Nesvadba, N, Epinat, B, Amram, P, Balkowski, C, Cesarsky, C, Dannerbauer, H, Di Serego Alighieri, S, Fuentes-Carrera, I, Guiderdoni, B, Kembhavi, A, Liang, YC, Östlin, G, Pozzetti, L, Ravikumar, CD, Rawat, A, Vergani, D, Vernet, A & Wozniak, H 2008, 'IMAGES: III. The evolution of the near-infrared Tully-Fisher relation over the last 6 Gyr', Astronomy and Astrophysics, vol. 484, no. 1, pp. 173-187. https://doi.org/10.1051/0004-6361:20079313

TY - JOUR

T1 - IMAGES

T2 - III. The evolution of the near-infrared Tully-Fisher relation over the last 6 Gyr

AU - Puech, M.

AU - Flores, H.

AU - Hammer, F.

AU - Yang, Y.

AU - Neichel, B.

AU - Lehnert, M.

AU - Chemin, L.

AU - Nesvadba, N.

AU - Epinat, B.

AU - Amram, P.

AU - Balkowski, C.

AU - Cesarsky, C.

AU - Dannerbauer, H.

AU - Di Serego Alighieri, S.

AU - Fuentes-Carrera, I.

AU - Guiderdoni, B.

AU - Kembhavi, A.

AU - Liang, Y. C.

AU - Östlin, G.

AU - Pozzetti, L.

AU - Ravikumar, C. D.

AU - Rawat, A.

AU - Vergani, D.

AU - Vernet, A.

AU - Wozniak, H.

PY - 2008/6

Y1 - 2008/6

N2 - Using the multi-integral field spectrograph GIRAFFE at VLT, we have derived the K-band Tully-Fisher relation (TFR) at z ≈ 0.6 for a representative sample of 65 galaxies with emission lines (W0(OII) ≈ 15 A). We confirm that the scatter in the z ≈ 0.6 TFR is caused by galaxies with anomalous kinematics, and find a positive and strong correlation between the complexity of the kinematics and the scatter that they contribute to the TFR. Considering only relaxed-rotating disks, the scatter, and possibly also the slope, of the TFR, do not appear to evolve with redshift. We detect an evolution of the K-band TFR zero point between z ≈ 0.6 and z = 0, which, if interpreted as an evolution of the K-band luminosity of rotating disks, would imply that a brightening of 0.66 ± 0.14 mag occurs between z ≈ 0.6 and z = 0. Any disagreement with the results of Flores et al. (2006, A&A, 455, 107) are attributed to both an improvement of the local TFR and the more detailed accurate measurement of the rotation velocities in the distant sample. Most of the uncertainty can be explained by the relatively coarse spatial-resolution of the kinematical data. Because most rotating disks at z ≈ 0.6 are unlikely to experience further merging events, one may assume that their rotational velocity, which is taken as a proxy of the total mass, does not evolve dramatically. If true, our result implies that rotating disks observed at z ≈ 0.6 are rapidly transforming their gas into stars, to be able to double their stellar masses and be observed on the TFR at z = 0. The rotating disks observed are indeed emission-line galaxies that are either starbursts or LIRGs, which implies that they are forming stars at a high rate. Thus, a significant fraction of the rotating disks are forming the bulk of their stars within 6 to 8 Gyr, in good agreement with former studies of the evolution of the mass-metallicity relationship.

AB - Using the multi-integral field spectrograph GIRAFFE at VLT, we have derived the K-band Tully-Fisher relation (TFR) at z ≈ 0.6 for a representative sample of 65 galaxies with emission lines (W0(OII) ≈ 15 A). We confirm that the scatter in the z ≈ 0.6 TFR is caused by galaxies with anomalous kinematics, and find a positive and strong correlation between the complexity of the kinematics and the scatter that they contribute to the TFR. Considering only relaxed-rotating disks, the scatter, and possibly also the slope, of the TFR, do not appear to evolve with redshift. We detect an evolution of the K-band TFR zero point between z ≈ 0.6 and z = 0, which, if interpreted as an evolution of the K-band luminosity of rotating disks, would imply that a brightening of 0.66 ± 0.14 mag occurs between z ≈ 0.6 and z = 0. Any disagreement with the results of Flores et al. (2006, A&A, 455, 107) are attributed to both an improvement of the local TFR and the more detailed accurate measurement of the rotation velocities in the distant sample. Most of the uncertainty can be explained by the relatively coarse spatial-resolution of the kinematical data. Because most rotating disks at z ≈ 0.6 are unlikely to experience further merging events, one may assume that their rotational velocity, which is taken as a proxy of the total mass, does not evolve dramatically. If true, our result implies that rotating disks observed at z ≈ 0.6 are rapidly transforming their gas into stars, to be able to double their stellar masses and be observed on the TFR at z = 0. The rotating disks observed are indeed emission-line galaxies that are either starbursts or LIRGs, which implies that they are forming stars at a high rate. Thus, a significant fraction of the rotating disks are forming the bulk of their stars within 6 to 8 Gyr, in good agreement with former studies of the evolution of the mass-metallicity relationship.

KW - Galaxies: evolution

KW - Galaxies: general

KW - Galaxies: high-redshift

KW - Galaxies: interactions

KW - Galaxies: kinematics and dynamics

KW - Galaxies: spiral

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U2 - 10.1051/0004-6361:20079313

DO - 10.1051/0004-6361:20079313

M3 - Artículo

SN - 0004-6361

VL - 484

SP - 173

EP - 187

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

IS - 1

ER -

IMAGES: III. The evolution of the near-infrared Tully-Fisher relation over the last 6 Gyr

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