Gamma-rays from cosmological sources contain information about gamma-ray interactions. Standard model and non-standard model photon interactions along the path between the source and the observer can lead to changes in the energy or state of the phot
ons, which in turn alters the observed energy spectrum of the source. In general, these interactions are a function of photon energy as well as source distance. Here we show how existing high energy (50 GeV -- 10TeV) gamma-ray observations of blazars can be used to constrain the coupling of axion-like-particles (ALPs) to the photon. The same ALP-photon coupling that has been invoked to explain the observations of TeV blazars beyond their pair production horizon is shown to have an effect of the data set of textit{Fermi} blazars.
Gamma-rays propagating through space are likely to be extinguished via electron-positron pair production off of the ambient extragalactic background light (EBL). The spectrum of the EBL is produced by starlight (and starlight reprocessed by dust) fro
m all galaxies throughout the history of the Universe. The attenuation of 40 - 400 GeV gamma-rays has been observed by textit{Fermi} and used to measure the EBL spectrum over energies 1 eV -10 eV out to redshift $zsim 1$. Measurements of several TeV blazers are consistent with attenuation, attributed to the EBL at redshift $zsim 0.1$. Here we simultaneously analyze a set of TeV blazers at $zsim 0.1$ to measure the optical depth for 100 GeV - 10 TeV gamma-rays, which interact with EBL of energies 0.05 eV - 5 eV. Using a suite of models for the EBL, we show that the optical depth indicated by TeV blazar attenuation is in good agreement with the optical depths measured by textit{Fermi} at lower gamma-ray energies and higher redshifts.
