Material Institut Lavoisier (MIL)-101, one of the metal-organic frameworks containing numerous coordinatively unsaturated sites, as well as high specific surface area, was synthetized under different protocols for CO2 adsorption and separation from N-2. To improve its CO2 adsorption capacity, different amounts [10, 25, and 40 wt % of tetraethylenepent-amine (TEPA)] were grafted to the parental MIL-101. Results revealed that TEPA-MIL-101 (40 wt %) showed one of the highest CO2 adsorption capacities (i.e., 3.76 mmol g(-1) at 298 K at 1 bar) among existing MIL-101 and its modified moieties. This amount was 1.56 times greater than parental MIL-101 (in spite of having superior textural properties), which adsorbed 2.41 mmol g(-1) CO2 at the same operational conditions. This can be attributed to the presence of polar functional groups in the porous between CO2 active sites on the adsorbent surface. Isosteric heat of adsorption of CO2 and N-2 on TEPA-MIL-101 (40 wt %) were 35 and 18 kJ mol(-1), respectively, based on the temperature-dependent form of the Freundlich model in the Clausius- Clapeyron equation. Ideal adsorption solution theory (LAST) was used for determination of CO2/N-2 selectivity for a binary gas mixture, including 15% CO2 and 85% N-2 at 298 K and at 1 bar. TEPA-MIL-101 (40 wt %) showed an exceptional CO2/N-2 selectivity of 220. Adsorption kinetics study demonstrated that the Avrami model was the best model for fitting the experimental data, which denotes that more than one pathway exists in CO2 and N-2 adsorption.