Shapes of luminous and dark matter in hydrodynamic simulations of galaxy mergers

G. S. Novak; T. J. Cox; J. R. Primack; P. Jonsson; A. Dekel

doi:10.1051/eas:2006096

Shapes of luminous and dark matter in hydrodynamic simulations of galaxy mergers

G. S. Novak^*, T. J. Cox, J. R. Primack, P. Jonsson, A. Dekel

^*Corresponding author for this work

Racah Institute of Physics

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

From a sample of more than 100 remnants from major and minor hydrodynamic binary galaxy merger simulations (Cox 2004; Cox et al. 2005), we find that stellar remnants are mostly oblate; while dark matter halos are mostly prolate or triaxlal. Shapes are determined by iteratively diagonalizing a moment-of-inertia tensor. The preferred axes of the two shapes are almost always nearly perpendicular. This can be understood by considering the influence of angular momentum and dissipation during the merger. If binary major mergers of spiral galaxies are responsible for the formation of elliptical galaxies or some subpopulation of elliptical galaxies, then the galaxies can be be expected to be oblate and the dark matter halos prolate with the two preferred axes perpendicular to each other.

Original language	English
Title of host publication	21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures
Pages	293-294
Number of pages	2
DOIs	https://doi.org/10.1051/eas:2006096
State	Published - 2006
Event	21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures - Paris, France Duration: 4 Jul 2005 → 9 Jul 2005

Publication series

Name	EAS Publications Series
Volume	20
ISSN (Print)	1633-4760

Conference

Conference	21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures
Country/Territory	France
City	Paris
Period	4/07/05 → 9/07/05

Access to Document

10.1051/eas:2006096

Cite this

@inproceedings{ae6085c9eda14d329b536e5c24b4d0aa,

title = "Shapes of luminous and dark matter in hydrodynamic simulations of galaxy mergers",

abstract = "From a sample of more than 100 remnants from major and minor hydrodynamic binary galaxy merger simulations (Cox 2004; Cox et al. 2005), we find that stellar remnants are mostly oblate; while dark matter halos are mostly prolate or triaxlal. Shapes are determined by iteratively diagonalizing a moment-of-inertia tensor. The preferred axes of the two shapes are almost always nearly perpendicular. This can be understood by considering the influence of angular momentum and dissipation during the merger. If binary major mergers of spiral galaxies are responsible for the formation of elliptical galaxies or some subpopulation of elliptical galaxies, then the galaxies can be be expected to be oblate and the dark matter halos prolate with the two preferred axes perpendicular to each other.",

author = "Novak, {G. S.} and Cox, {T. J.} and Primack, {J. R.} and P. Jonsson and A. Dekel",

year = "2006",

doi = "10.1051/eas:2006096",

language = "אנגלית",

isbn = "2868839177",

series = "EAS Publications Series",

pages = "293--294",

booktitle = "21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures",

note = "21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures ; Conference date: 04-07-2005 Through 09-07-2005",

}

Novak, GS, Cox, TJ, Primack, JR, Jonsson, P & Dekel, A 2006, Shapes of luminous and dark matter in hydrodynamic simulations of galaxy mergers. in 21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures. EAS Publications Series, vol. 20, pp. 293-294, 21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures, Paris, France, 4/07/05. https://doi.org/10.1051/eas:2006096

TY - GEN

T1 - Shapes of luminous and dark matter in hydrodynamic simulations of galaxy mergers

AU - Novak, G. S.

AU - Cox, T. J.

AU - Primack, J. R.

AU - Jonsson, P.

AU - Dekel, A.

PY - 2006

Y1 - 2006

N2 - From a sample of more than 100 remnants from major and minor hydrodynamic binary galaxy merger simulations (Cox 2004; Cox et al. 2005), we find that stellar remnants are mostly oblate; while dark matter halos are mostly prolate or triaxlal. Shapes are determined by iteratively diagonalizing a moment-of-inertia tensor. The preferred axes of the two shapes are almost always nearly perpendicular. This can be understood by considering the influence of angular momentum and dissipation during the merger. If binary major mergers of spiral galaxies are responsible for the formation of elliptical galaxies or some subpopulation of elliptical galaxies, then the galaxies can be be expected to be oblate and the dark matter halos prolate with the two preferred axes perpendicular to each other.

AB - From a sample of more than 100 remnants from major and minor hydrodynamic binary galaxy merger simulations (Cox 2004; Cox et al. 2005), we find that stellar remnants are mostly oblate; while dark matter halos are mostly prolate or triaxlal. Shapes are determined by iteratively diagonalizing a moment-of-inertia tensor. The preferred axes of the two shapes are almost always nearly perpendicular. This can be understood by considering the influence of angular momentum and dissipation during the merger. If binary major mergers of spiral galaxies are responsible for the formation of elliptical galaxies or some subpopulation of elliptical galaxies, then the galaxies can be be expected to be oblate and the dark matter halos prolate with the two preferred axes perpendicular to each other.

UR - http://www.scopus.com/inward/record.url?scp=33746066709&partnerID=8YFLogxK

U2 - 10.1051/eas:2006096

DO - 10.1051/eas:2006096

M3 - ???researchoutput.researchoutputtypes.contributiontobookanthology.conference???

AN - SCOPUS:33746066709

SN - 2868839177

SN - 9782868839176

T3 - EAS Publications Series

SP - 293

EP - 294

BT - 21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures

T2 - 21st IAP Colloquium Mass Profiles and Shapes of Cosmological Structures

Y2 - 4 July 2005 through 9 July 2005

ER -

Shapes of luminous and dark matter in hydrodynamic simulations of galaxy mergers

Abstract

Publication series

Conference

Access to Document

Other files and links

Fingerprint

Cite this