[摘要] Very-high-energy gamma ray photons (VHE; E > 100 GeV) from distant gamma ray objects(e.g. blazars) are expected to be absorbed by the diffuse extragalactic background light (EBL),which leads to a high-energy cut-off in a blazar's spectral energy distribution (SED). Butrecent observations of cosmological gamma ray sources, after correction for the standard EBLabsorption, have been interpreted by some authors that the Universe is more transparent toVHE gamma rays than expected from our current knowledge of the EBL energy density andcosmological evolution. These unexpected VHE gamma ray signatures are currently one of thesubjects of intensive research.One of the suggested solutions to this problem is the hypothesis that a reduced EBL opacityresults from the EBL energy density inhomogeneities in particular if the line of sight to a blazaris passing through a cosmic void (under-dense region) in intergalactic space.In this thesis, we start by studying the effects of such inhomogeneities on the energy density ofthe EBL and the resulting gamma-gamma opacity, speciffically, by investigating the effects ofcosmic void along the line of sight to a distant blazar. First, we studied the possibility of onesingle void and then the possibility of multiple voids, by assuming an accumulation of voids (10voids) of typical radii R = 100 h -1 Mpc centred at a redshift of zv = 0:3 along the line of sightto an object (for example, a blazar) located at redshift zv = 0:6. We conclude that spectralhardening of the VHE gamma ray spectrum for blazars (e.g. PKS 1424+240), after correctionfor the EBL gamma ray attenuation, is most likely not an artifact of an over-estimation of theEBL absorption due to cosmic inhomogeneities.In the second part of this thesis, we considered the impact of the Lorentz Invariance Violation(LIV) effect on the gamma-gamma opacity of the Universe to VHE gamma rays propagatingfrom a distant object, compared with the possibility of multiple voids along the line of sight(LOS) to the same object, and we investigated the impact of the LIV effect on the Comptoneffect. Both subluminal and superluminal modifications of the dispersion relation of photonsare considered. In the subluminal scenario, the LIV effects may result in a significant reductiondue to the gamma-gamma absorption for photons with energies & 10 TeV. However, theeffect is not expected to be sufficient to explain the apparent spectral hardening of severalobserved VHE gamma ray blazars in the energy range from 100 GeV up to few TeVs, evenwhen including effects of the EBL inhomogeneities in the distributions of matter and light inthe intergalactic space. superluminal modifications of the dispersion relation of photons lead toa further enhancement of the EBL gamma-gamma absorption. We consider, for the first time,the influence of LIV on the Compton effect. We find that the modified Compton scatteringprocess due to the LIV effect becomes relevant only for photons with energies, E & 1 PeV. Inthe case of a superluminal modification of the photon dispersion relation, both the kinematicrecoil effect and the Klein-Nishina suppression of the cross-section are reduced. However, weargue that the impact of LIV e ect on the Compton scattering process is unlikely to be ofastrophysical significance.