A Consistent Approach to Falsifying Lambda-CDM with Rare Galaxy Clusters. Harrison, I. & Hotchkiss, S. Journal of Cosmology and Astroparticle Physics, 2013(07):022–022, July, 2013. arXiv: 1210.4369
A Consistent Approach to Falsifying Lambda-CDM with Rare Galaxy Clusters [link]Paper  doi  abstract   bibtex   
We consider methods with which to answer the question "is any observed galaxy cluster too unusual for Lambda-CDM?" After emphasising that many previous attempts to answer this question will overestimate the confidence level at which Lambda-CDM can be ruled out, we outline a consistent approach to these rare clusters, which allows the question to be answered. We define three statistical measures, each of which are sensitive to changes in cluster populations arising from different modifications to the cosmological model. We also use these properties to define the 'equivalent mass at redshift zero' for a cluster — the mass of an equally unusual cluster today. This quantity is independent of the observational survey in which the cluster was found, which makes it an ideal proxy for ranking the relative unusualness of clusters detected by different surveys. These methods are then used on a comprehensive sample of observed galaxy clusters and we confirm that all are less than 2-sigma deviations from the Lambda-CDM expectation. Whereas we have only applied our method to galaxy clusters, it is applicable to any isolated, collapsed, halo. As motivation for future surveys, we also calculate where in the mass redshift plane the rarest halo is most likely to be found, giving information as to which objects might be the most fruitful in the search for new physics.
@article{harrison_consistent_2013,
	title = {A {Consistent} {Approach} to {Falsifying} {Lambda}-{CDM} with {Rare} {Galaxy} {Clusters}},
	volume = {2013},
	issn = {1475-7516},
	url = {http://arxiv.org/abs/1210.4369},
	doi = {10.1088/1475-7516/2013/07/022},
	abstract = {We consider methods with which to answer the question "is any observed galaxy cluster too unusual for Lambda-CDM?" After emphasising that many previous attempts to answer this question will overestimate the confidence level at which Lambda-CDM can be ruled out, we outline a consistent approach to these rare clusters, which allows the question to be answered. We define three statistical measures, each of which are sensitive to changes in cluster populations arising from different modifications to the cosmological model. We also use these properties to define the 'equivalent mass at redshift zero' for a cluster --- the mass of an equally unusual cluster today. This quantity is independent of the observational survey in which the cluster was found, which makes it an ideal proxy for ranking the relative unusualness of clusters detected by different surveys. These methods are then used on a comprehensive sample of observed galaxy clusters and we confirm that all are less than 2-sigma deviations from the Lambda-CDM expectation. Whereas we have only applied our method to galaxy clusters, it is applicable to any isolated, collapsed, halo. As motivation for future surveys, we also calculate where in the mass redshift plane the rarest halo is most likely to be found, giving information as to which objects might be the most fruitful in the search for new physics.},
	number = {07},
	urldate = {2015-12-07},
	journal = {Journal of Cosmology and Astroparticle Physics},
	author = {Harrison, Ian and Hotchkiss, Shaun},
	month = jul,
	year = {2013},
	note = {arXiv: 1210.4369},
	keywords = {Astrophysics - Cosmology and Nongalactic Astrophysics},
	pages = {022--022},
}

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