The device performance of the membrane gas absorption system was investigated theoretically and experimentally in the present study. A two-dimensional mathematical formulation was developed in a hollow fiber gas–liquid membrane contactor with gas and liquid flow rates regulated independently. Physical absorption of carbon dioxide by amine was carried out and illustrated to validate the theoretical predictions. The resultant partial differential equations, as referred to conjugated Graetz problems, were solved analytically using the separated variable method associated with an orthogonal expansion technique. The absorption efficiency was studied with the absorbent flow rate, gas feed flow rate and CO2 concentration in the gas feed as parameters. The theoretical predictions show that the effect of the initial carbon dioxide concentration in the gas feed on the absorption efficiency is match. The influences of operating and design parameters on the absorption efficiency and total absorption rate are also discussed.