Evidence for a new light spin-zero boson from cosmological gamma-ray propagation?

Abstract

Recent findings by Imaging Atmospheric Cherenkov Telescopes indicate a large transparency of the Universe to gamma rays, which can be hardly explained within the current models of extragalactic background light. We show that the observed transparency is naturally produced by an oscillation mechanism -- which can occur inside intergalactic magnetic fields -- whereby a photon can become a new spin-zero boson with mass m << 10^(-10) eV. Because the latter particle travels unimpeded throughout the Universe, photons can reach the observer even if the distance from the source considerably exceeds their mean free path. We compute the expected flux of gamma rays from blazar 3C279 at different energies. Our predictions can be tested in the near future by the gamma-ray telescopes H.E.S.S., MAGIC, CANGAROO and VERITAS. Moreover, our result provides an important observational test for models of dark energy wherein quintessence is coupled to the photon through an effective dimension-five operator.

Figures (1)

• Figure 1: The two lowest lines give the fraction of photons surviving from a source at the same distance of 3C279 without the oscillation mechanism, for the "best-fit model" of EBL (dashed line) and for the minimum EBL density compatible with cosmology kneiske. The solid line represents the prediction of the oscillation mechanism for $B \simeq 10^{-9}\,{\rm G}$ and $L_{\rm dom} \simeq 1\,{\rm Mpc}$ within the "best-fit model" of EBL. The gray band is the envelope of the results obtained by independently changing ${\bf B}$ and $L_{\rm dom}$ within a factor of 10 about their preferred values.