The dark energy plus cold dark matter (\$Łambda\$CDM) cosmological model has
been a demonstrably successful framework for predicting and explaining the
large-scale structure of Universe and its evolution with time. Yet on length
scales smaller than \$1\$ Mpc and mass scales smaller than \$10^11
M\_ødot\$, the theory faces a number of challenges. For example, the observed
cores of many dark-matter dominated galaxies are both less dense and less cuspy
than naively predicted in \$Łambda\$CDM. The number of small galaxies and dwarf
satellites in the Local Group is also far below the predicted count of low-mass
dark matter halos and subhalos within similar volumes. These issues underlie
the most well-documented problems with \$Łambda\$CDM: Cusp/Core, Missing
Satellites, and Too-Big-to-Fail. The key question is whether a better
understanding of baryon physics, dark matter physics, or both will be required
to meet these challenges. Other anomalies, including the observed planar and
orbital configurations of Local Group satellites and the tight baryonic/dark
matter scaling relations obeyed by the galaxy population, have been less
thoroughly explored in the context of \$Łambda\$CDM theory. Future surveys to
discover faint, distant dwarf galaxies and to precisely measure their masses
and density structure hold promising avenues for testing possible solutions to
the small-scale challenges going forward. Observational programs to constrain
or discover and characterize the number of truly dark low-mass halos are among
the most important, and achievable, goals in this field over then next decade.
These efforts will either further verify the \$Łambda\$CDM paradigm or demand a
substantial revision in our understanding of the nature of dark matter.
%0 Journal Article
%1 citeulike:14394801
%A Bullock, James S.
%A Boylan-Kolchin, Michael
%D 2017
%J Annual Review of Astronomy and Astrophysics
%K imported
%N 1
%R 10.1146/annurev-astro-091916-055313
%T Small-Scale Challenges to the \$Łambda\$CDM Paradigm
%U http://dx.doi.org/10.1146/annurev-astro-091916-055313
%V 55
%X The dark energy plus cold dark matter (\$Łambda\$CDM) cosmological model has
been a demonstrably successful framework for predicting and explaining the
large-scale structure of Universe and its evolution with time. Yet on length
scales smaller than \$1\$ Mpc and mass scales smaller than \$10^11
M\_ødot\$, the theory faces a number of challenges. For example, the observed
cores of many dark-matter dominated galaxies are both less dense and less cuspy
than naively predicted in \$Łambda\$CDM. The number of small galaxies and dwarf
satellites in the Local Group is also far below the predicted count of low-mass
dark matter halos and subhalos within similar volumes. These issues underlie
the most well-documented problems with \$Łambda\$CDM: Cusp/Core, Missing
Satellites, and Too-Big-to-Fail. The key question is whether a better
understanding of baryon physics, dark matter physics, or both will be required
to meet these challenges. Other anomalies, including the observed planar and
orbital configurations of Local Group satellites and the tight baryonic/dark
matter scaling relations obeyed by the galaxy population, have been less
thoroughly explored in the context of \$Łambda\$CDM theory. Future surveys to
discover faint, distant dwarf galaxies and to precisely measure their masses
and density structure hold promising avenues for testing possible solutions to
the small-scale challenges going forward. Observational programs to constrain
or discover and characterize the number of truly dark low-mass halos are among
the most important, and achievable, goals in this field over then next decade.
These efforts will either further verify the \$Łambda\$CDM paradigm or demand a
substantial revision in our understanding of the nature of dark matter.
@article{citeulike:14394801,
abstract = {The dark energy plus cold dark matter (\$\Lambda\$CDM) cosmological model has
been a demonstrably successful framework for predicting and explaining the
large-scale structure of Universe and its evolution with time. Yet on length
scales smaller than \$\sim 1\$ Mpc and mass scales smaller than \$\sim 10^{11}
M\_{\odot}\$, the theory faces a number of challenges. For example, the observed
cores of many dark-matter dominated galaxies are both less dense and less cuspy
than naively predicted in \$\Lambda\$CDM. The number of small galaxies and dwarf
satellites in the Local Group is also far below the predicted count of low-mass
dark matter halos and subhalos within similar volumes. These issues underlie
the most well-documented problems with \$\Lambda\$CDM: Cusp/Core, Missing
Satellites, and Too-Big-to-Fail. The key question is whether a better
understanding of baryon physics, dark matter physics, or both will be required
to meet these challenges. Other anomalies, including the observed planar and
orbital configurations of Local Group satellites and the tight baryonic/dark
matter scaling relations obeyed by the galaxy population, have been less
thoroughly explored in the context of \$\Lambda\$CDM theory. Future surveys to
discover faint, distant dwarf galaxies and to precisely measure their masses
and density structure hold promising avenues for testing possible solutions to
the small-scale challenges going forward. Observational programs to constrain
or discover and characterize the number of truly dark low-mass halos are among
the most important, and achievable, goals in this field over then next decade.
These efforts will either further verify the \$\Lambda\$CDM paradigm or demand a
substantial revision in our understanding of the nature of dark matter.},
added-at = {2019-03-25T08:20:55.000+0100},
archiveprefix = {arXiv},
author = {Bullock, James S. and Boylan-Kolchin, Michael},
biburl = {https://www.bibsonomy.org/bibtex/2424b8e0a6f3978aab2be84479fbc6a92/ericblackman},
citeulike-article-id = {14394801},
citeulike-linkout-0 = {http://arxiv.org/abs/1707.04256},
citeulike-linkout-1 = {http://arxiv.org/pdf/1707.04256},
citeulike-linkout-2 = {http://dx.doi.org/10.1146/annurev-astro-091916-055313},
day = 13,
doi = {10.1146/annurev-astro-091916-055313},
eprint = {1707.04256},
interhash = {7a28c3ed9df23b591bad2e4ef7e30b6a},
intrahash = {424b8e0a6f3978aab2be84479fbc6a92},
issn = {0066-4146},
journal = {Annual Review of Astronomy and Astrophysics},
keywords = {imported},
month = jul,
number = 1,
posted-at = {2017-07-20 20:44:03},
priority = {2},
timestamp = {2019-03-25T08:20:55.000+0100},
title = {{Small-Scale Challenges to the \$\Lambda\$CDM Paradigm}},
url = {http://dx.doi.org/10.1146/annurev-astro-091916-055313},
volume = 55,
year = 2017
}