Dark matter cores all the way down
(2016) In Monthly Notices of the Royal Astronomical Society 459(3). p.2573-2590- Abstract
We use high-resolution simulations of isolated dwarf galaxies to study the physics of dark matter cusp-core transformations at the edge of galaxy formation: M200 = 107-109 M⊙. We work at a resolution (~4 pc minimum cell size; ~250 M⊙ per particle) at which the impact from individual supernovae explosions can be resolved, becoming insensitive to even large changes in our numerical 'sub-grid' parameters. We find that our dwarf galaxies give a remarkable match to the stellar light profile; star formation history; metallicity distribution function; and star/gas kinematics of isolated dwarf irregular galaxies. Our key result is that dark matter cores of size comparable to the stellar... (More)
We use high-resolution simulations of isolated dwarf galaxies to study the physics of dark matter cusp-core transformations at the edge of galaxy formation: M200 = 107-109 M⊙. We work at a resolution (~4 pc minimum cell size; ~250 M⊙ per particle) at which the impact from individual supernovae explosions can be resolved, becoming insensitive to even large changes in our numerical 'sub-grid' parameters. We find that our dwarf galaxies give a remarkable match to the stellar light profile; star formation history; metallicity distribution function; and star/gas kinematics of isolated dwarf irregular galaxies. Our key result is that dark matter cores of size comparable to the stellar half-mass radius r1/2 always form if star formation proceeds for long enough. Cores fully form in less than 4 Gyr for the M200 = 108 M⊙ and ~14 Gyr for the 109 M⊙ dwarf. We provide a convenient two parameter 'coreNFW' fitting function that captures this dark matter core growth as a function of star formation time and the projected stellar half-mass radius. Our results have several implications: (i) we make a strong prediction that if Λcold dark matter is correct, then 'pristine' dark matter cusps will be found either in systems that have truncated star formation and/or at radii r > r1/2; (ii) complete core formation lowers the projected velocity dispersion at r1/2 by a factor of ~2, which is sufficient to fully explain the 'too-big-to-fail problem'; and (iii) cored dwarfs will be much more susceptible to tides, leading to a dramatic scouring of the sub-halo mass function inside galaxies and groups.
(Less)
- author
- Read, J. I. ; Agertz, O. LU and Collins, M. L M
- publishing date
- 2016-07-01
- type
- Contribution to journal
- publication status
- published
- keywords
- Dark matter, Galaxies: dwarf, Galaxies: haloes, Galaxies: kinematics and dynamics, Methods: numerical
- in
- Monthly Notices of the Royal Astronomical Society
- volume
- 459
- issue
- 3
- pages
- 18 pages
- publisher
- Oxford University Press
- external identifiers
-
- scopus:84975092121
- ISSN
- 0035-8711
- DOI
- 10.1093/mnras/stw713
- language
- English
- LU publication?
- no
- id
- 8a1d5525-e4e5-4436-bc3b-83d3f6c2ddb5
- date added to LUP
- 2016-08-16 22:54:43
- date last changed
- 2022-04-01 01:38:58
@article{8a1d5525-e4e5-4436-bc3b-83d3f6c2ddb5, abstract = {{<p>We use high-resolution simulations of isolated dwarf galaxies to study the physics of dark matter cusp-core transformations at the edge of galaxy formation: M<sub>200</sub> = 10<sup>7</sup>-10<sup>9</sup> M<sub>⊙</sub>. We work at a resolution (~4 pc minimum cell size; ~250 M<sub>⊙</sub> per particle) at which the impact from individual supernovae explosions can be resolved, becoming insensitive to even large changes in our numerical 'sub-grid' parameters. We find that our dwarf galaxies give a remarkable match to the stellar light profile; star formation history; metallicity distribution function; and star/gas kinematics of isolated dwarf irregular galaxies. Our key result is that dark matter cores of size comparable to the stellar half-mass radius r<sub>1/2</sub> always form if star formation proceeds for long enough. Cores fully form in less than 4 Gyr for the M<sub>200</sub> = 10<sup>8</sup> M<sub>⊙</sub> and ~14 Gyr for the 10<sup>9</sup> M<sub>⊙</sub> dwarf. We provide a convenient two parameter 'coreNFW' fitting function that captures this dark matter core growth as a function of star formation time and the projected stellar half-mass radius. Our results have several implications: (i) we make a strong prediction that if Λcold dark matter is correct, then 'pristine' dark matter cusps will be found either in systems that have truncated star formation and/or at radii r > r<sub>1/2</sub>; (ii) complete core formation lowers the projected velocity dispersion at r<sub>1/2</sub> by a factor of ~2, which is sufficient to fully explain the 'too-big-to-fail problem'; and (iii) cored dwarfs will be much more susceptible to tides, leading to a dramatic scouring of the sub-halo mass function inside galaxies and groups.</p>}}, author = {{Read, J. I. and Agertz, O. and Collins, M. L M}}, issn = {{0035-8711}}, keywords = {{Dark matter; Galaxies: dwarf; Galaxies: haloes; Galaxies: kinematics and dynamics; Methods: numerical}}, language = {{eng}}, month = {{07}}, number = {{3}}, pages = {{2573--2590}}, publisher = {{Oxford University Press}}, series = {{Monthly Notices of the Royal Astronomical Society}}, title = {{Dark matter cores all the way down}}, url = {{http://dx.doi.org/10.1093/mnras/stw713}}, doi = {{10.1093/mnras/stw713}}, volume = {{459}}, year = {{2016}}, }