We consider the evolution of the vacuum energy in the Dvali-Gabadadze-Porrati (DGP) model according to the holographic principle under the assumption that the relation linking the IR and UV cutoffs still holds in this scenario. The model is studied when the IR cutoff is chosen to be the Hubble scale $H^{-1}$, the particle horizon $R_{\mathrm{ph}}$, and the future event horizon $R_{\mathrm{eh}}$, respectively. The two branches of the DGP model are also taken into account. Through numerical analysis, we find that in the cases of $H^{-1}$ in the ($+$) branch and $R_{\mathrm{eh}}$ in both branches, the vacuum energy can play the role of dark energy. Moreover, when considering the combination of the vacuum energy and the $5\mathrm{D}$ gravity effect in both branches, the equation of state of the effective dark energy may cross $-1$, which may lead to the big rip singularity. Besides, we constrain the model with the Type Ia supernovae and baryon oscillation data and find that our model is consistent with current data within $1\sigma$, and that the observations prefer either a pure holographic dark energy or a pure DGP model.

• Received 3 October 2007

DOI:https://doi.org/10.1103/PhysRevD.77.043502