This study focuses on the effect of a silicon rubber coating technique on the hollow fiber membrane contactor for the
purpose of CO2 removal. The polymer and the coating agent used were polyetherimide (PEI) and polydimethylsiloxane
(PDMS) respectively. The hollow fibers were fabricated via a simple wet spinning technique. The surfaces of the hollow
fibers were coated by means of PDMS dissolved in n-hexane applying different protocols. An effort was made to keep
the silicon rubber coating layer porous. The membranes were characterized by applying gas permeation test (GPT) via
pure helium, critical entry pressure of water (CEPw), contact angle, gas absorption test and scanning electron
microscopy (SEM). Based on the observations, the coating technique resulted in drastic changes in the contact angle and
CEPw of the coated membranes for the inside and outside coated hollow fiber membranes in common. Disregarding the
method of coating and even the polymer concentration, the contact angle has been enhanced dramatically. The CO2
absorption results revealed that by blowing nitrogen (600 kPa) through the lumen side of the hollow fibers during the
PDMS coating process onto the outside surface, the absorption flux of the membranes was increased. A slight decrease
in CO2 absorption flux for the other cases was outweighed by a substantial enhancement in the membrane wetting
resistant due to the high contact angle and CEPw. These observations showed the high influence of the silicon rubber
layer on the CO2 gas absorption, which emphasizes the role of this key-parameter in controlling the ultimate membrane
contactor performance.