The ALP miracle revisited

Ryuji Daido; Fuminobu Takahashi; Wen Yin

The ALP miracle revisited

Ryuji Daido, Fuminobu Takahashi, Wen Yin

SCI - Physics

Research output: Contribution to journal › Article › peer-review

Abstract

We revisit the ALP miracle scenario where the inflaton and dark matter are unified by a single axion-like particle (ALP). We first extend our previous analysis on the inflaton dynamics to identify the whole viable parameter space consistent with the CMB observation. Then, we evaluate the relic density of the ALP dark matter by incorporating uncertainties of the model-dependent couplings to the weak gauge bosons as well as the dissipation effect. The preferred ranges of the ALP mass and coupling to photons are found to be 0.01 < m < 1eV and g$∼_ri= 0(10^-11) GeV^-1, which slightly depend on these uncertainties. Interestingly, the preferred regions are within the reach of future solar axion helioscope experiments IAXO and TASTE and laser-based stimulated photon-photon collider experiments. We also discuss possible extensions of the ALP miracle scenario by introducing interactions of the ALP with fermions.

Original language	English
Journal	Unknown Journal
Publication status	Published - 2017 Oct 30

ASJC Scopus subject areas

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abstract = "We revisit the ALP miracle scenario where the inflaton and dark matter are unified by a single axion-like particle (ALP). We first extend our previous analysis on the inflaton dynamics to identify the whole viable parameter space consistent with the CMB observation. Then, we evaluate the relic density of the ALP dark matter by incorporating uncertainties of the model-dependent couplings to the weak gauge bosons as well as the dissipation effect. The preferred ranges of the ALP mass and coupling to photons are found to be 0.01 < m < 1eV and g$∼ri= 0(10-11) GeV-1, which slightly depend on these uncertainties. Interestingly, the preferred regions are within the reach of future solar axion helioscope experiments IAXO and TASTE and laser-based stimulated photon-photon collider experiments. We also discuss possible extensions of the ALP miracle scenario by introducing interactions of the ALP with fermions.",

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T1 - The ALP miracle revisited

AU - Daido, Ryuji

AU - Takahashi, Fuminobu

AU - Yin, Wen

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N2 - We revisit the ALP miracle scenario where the inflaton and dark matter are unified by a single axion-like particle (ALP). We first extend our previous analysis on the inflaton dynamics to identify the whole viable parameter space consistent with the CMB observation. Then, we evaluate the relic density of the ALP dark matter by incorporating uncertainties of the model-dependent couplings to the weak gauge bosons as well as the dissipation effect. The preferred ranges of the ALP mass and coupling to photons are found to be 0.01 < m < 1eV and g$∼ri= 0(10-11) GeV-1, which slightly depend on these uncertainties. Interestingly, the preferred regions are within the reach of future solar axion helioscope experiments IAXO and TASTE and laser-based stimulated photon-photon collider experiments. We also discuss possible extensions of the ALP miracle scenario by introducing interactions of the ALP with fermions.

AB - We revisit the ALP miracle scenario where the inflaton and dark matter are unified by a single axion-like particle (ALP). We first extend our previous analysis on the inflaton dynamics to identify the whole viable parameter space consistent with the CMB observation. Then, we evaluate the relic density of the ALP dark matter by incorporating uncertainties of the model-dependent couplings to the weak gauge bosons as well as the dissipation effect. The preferred ranges of the ALP mass and coupling to photons are found to be 0.01 < m < 1eV and g$∼ri= 0(10-11) GeV-1, which slightly depend on these uncertainties. Interestingly, the preferred regions are within the reach of future solar axion helioscope experiments IAXO and TASTE and laser-based stimulated photon-photon collider experiments. We also discuss possible extensions of the ALP miracle scenario by introducing interactions of the ALP with fermions.

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