Warm dark matter (WDM) consists of particles with masses in the keV range that remain relativistic longer than cold dark matter. Because they travel faster in the early universe, they can erase density perturbations below a characteristic scale known as the freeβstreaming length. This suppression influences the formation of lowβmass halos and can be probed by observations of dwarf galaxies and the LymanβΞ± forest.
The freeβstreaming mass, (M_{mathrm{fs}}), is the mass contained within a sphere whose radius equals half the freeβstreaming length. It provides a convenient way to express the smallest structures that can form in a WDM cosmology. The mass depends on the particle mass (m_{mathrm{wdm}}), the WDM density parameter (Omega_{mathrm{wdm}}), and the reduced Hubble constant (h).
A widely used approximation for the freeβstreaming mass is
What is warm dark matter?
How does warm dark matter affect galaxy formation?
What is the free-streaming length in this context?
How do observations of dwarf galaxies probe warm dark matter?
What is the Lyman-Ξ± forest in relation to warm dark matter?
How does the free-streaming mass relate to particle speed?
What is the significance of the keV range for warm dark matter particles?
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