Relic thermal axions could play the role of an extra hot dark matter component in cosmological structure formation theories. By combining the most recent observational data we improve previous cosmological bounds on the axion mass m(a) in the so-called hadronic axion window. We obtain a limit on the axion mass m(a)< 0.42 eV at the 95% C.L. (m(a)< 0.72 eV at the 99% C.L.). A novel aspect of the analysis presented here is the inclusion of massive neutrinos and how they may affect the bound on the axion mass. If neutrino masses belong to an inverted hierarchy scheme, for example, the above constraint is improved to m(a)< 0.38 eV at the 95% C.L. (m(a)< 0.67 eV at the 99% C.L.). Future data from experiments as CAST will provide a direct test of the cosmological bound.
Improved cosmological bound on the thermal axion mass / Melchiorri, Alessandro; Olga, Mena; Anze, Slosar. - In: PHYSICAL REVIEW D, PARTICLES, FIELDS, GRAVITATION, AND COSMOLOGY. - ISSN 1550-7998. - 76:4(2007), pp. 041303-041306. [10.1103/physrevd.76.041303]
Improved cosmological bound on the thermal axion mass
MELCHIORRI, Alessandro;
2007
Abstract
Relic thermal axions could play the role of an extra hot dark matter component in cosmological structure formation theories. By combining the most recent observational data we improve previous cosmological bounds on the axion mass m(a) in the so-called hadronic axion window. We obtain a limit on the axion mass m(a)< 0.42 eV at the 95% C.L. (m(a)< 0.72 eV at the 99% C.L.). A novel aspect of the analysis presented here is the inclusion of massive neutrinos and how they may affect the bound on the axion mass. If neutrino masses belong to an inverted hierarchy scheme, for example, the above constraint is improved to m(a)< 0.38 eV at the 95% C.L. (m(a)< 0.67 eV at the 99% C.L.). Future data from experiments as CAST will provide a direct test of the cosmological bound.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
