Differentiating Dilatons from Axions by their mixing with photons

Abstract

According to the model (), based on deep cosmological observations, the current universe is constituted of 5\% baryonic matter and 25 \% non-baryonic cold dark matter (of speculative origin). These include quanta of scalar filed like dilaton(φ) of scale symmetry origin and quanta of pseudoscalar field of extra standard model symmetry ( Peccei-Quinn) origin, like axion (φ'). These fields couple to di-photons through dim-5 operators. In magnetized medium, they in principle can interact with the three degrees of freedom (two transverse (A,) and one longitudinal (AL)) of photon(γ) as long as the total spin is conserved. Because of intrinsic spin being zero, both φ and φ' could in principle have interacted with AL, (having sz=0). However, out of φ and φ' only one interacts with AL. Furthermore, the ambient external magnetic field and media, breaks the intrinsic Lorentz symmetry of the system invoking Charge conjugation, Parity and Time reversal symmetries, we analyse the mixing dynamics of φγ and φ'γ systems and the structural difference of their mixing pattern. The strength of electromagnetic (EM) signals due to φγ and φ'γ mixing as a result would be different. We conclude by commenting on the possibility of detecting this difference -- in polarimetric observables the EMS -- using the existing space-borne detectors.