Polymer-based nanocomposites were prepared by solution blending of polyhedral oligomeric silsesquioxane with phenethyl substituents (PhenethylPOSS) into poly(bisphenol A carbonate) (PBAC). First investigations focused on structure, morphology and dynamics, addressed mainly by dielectric relaxation spectroscopy are substantially extended in this study by the investigation of the CO2gas transport behavior of these materials, i.e., permeation experiments using the time-lag technique as well as gravimetric gas sorption measurements. The nanocomposite materials were prepared with nanofiller contents ranging from 0 to about 40 wt % by solution blending and films of about 50−100 μm thickness were cast from this solution and used for the investigation of gas transport properties after drying and annealing. From the time-lag measurements the permeability and an effective diffusion coefficient for CO2is obtained in dependence of POSS concentration and temperature. As main results, both, the permeability and the diffusivity, increase whereas the solubility decreases with increasing POSS concentration. These findings are discussed in the framework of a microphase separated morphology of the nanocomposite systems for POSS concentrations greater than a value cPOSScritof ca. 7 wt % consisting of a polycarbonate-rich matrix and POSS-rich domains which are surrounded by an interfacial layer. The experimental solubility data suggest that the POSS-rich domains are more or less impermeable for CO2. On the basis of this assumption a quantitative model is provided to correct the solubility data for the phase separated morphology. Moreover the importance of the interfacial layer between the POSS particles or its domains for the properties of nanocomposites especially for the gas transport behavior is addressed by analyzing the sorption isotherms. Also, for the first time results from gas transport measurements and dielectric spectroscopy were quantitatively related to each other by taking the activation energies of CO2diffusion and of the dielectric β-relaxation into consideration. The obtained clear correlation indicates that the CO2gas transport is due to localized molecular fluctuations. As a further result, the diffusion coefficient obtained from time-lag and gas sorption measurements is in good agreement with respect to both their absolute values and in their concentration dependence.