期刊
ASTROPHYSICAL JOURNAL
卷 546, 期 2, 页码 L77-L80出版社
UNIV CHICAGO PRESS
DOI: 10.1086/318861
关键词
cosmic microwave background; cosmology : theory; dark matter; galaxies : formation; large-scale structure of universe
The canonical cosmological constant-dominated cold dark matter model (Lambda CDM) may possess too much power on small scales at z=0, manifested as central overconcentration of dark matter and overabundance of dwarf galaxies. We suggest an alternative model, Lambda DCDM, where one-half of the cold dark matter particles decay into relativistic particles by z=0. The model successfully lowers the concentration of dark matter in dwarf galaxies as well as in large galaxies like our own at low redshift while simultaneously retaining the virtues of the Lambda CDM model. The model solves the problem of overproduction of small dwarf galaxies in the Lambda CDM, not by removing them but by identifying them with failed, dark galaxies, where star formation is quenched as a result of dark matter evaporation and consequent halo expansion. A dramatic difference between the Lambda DCDM model and other proposed variants of the LCDM model is that the small-scale power at high redshift (z>2) in the Lambda DCDM model is enhanced compared to the LCDM model. A COBE- and cluster-normalized Lambda DCDM model can be constructed with the following parameters: H-o = 60 km s(-1) Mpc(-1), lambda (o) = 0.60, Omega (0,CDM) = 0.234, Omega (0,b) = 0.044 n = 1.0, and sigma (8) = 1.06. A clean test of this model can be made by measuring the evolution of the gas fraction in clusters. The prediction is that the gas fraction should decrease with redshift and is smaller by 31% at z = 1 than at z=0. X-ray and Sunyaev-Zeldovich effect observations should provide such a test.
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