Abstract
In this paper, two triazine ring-containing quaternary ammonium salt Gemini surfactants (C(12)-2-C(12) and C(14)-2-C(14)) were synthesized. The minimum inhibitory concentrations against sulfate-reducing bacteria (SRB) of C(12)-2-C(12), C(14)-2-C(14) and dodecyl dimethyl benzyl ammonium chloride (1227) were determined using the double-dilution method. The performance of C(12)-2-C(12) and C(14)-2-C(14) in inhibiting carbon steel corrosion in the presence of SRB was examined, with 1227 serving as a control sample. The corrosion inhibition properties were assessed through static weight loss, electrochemical testing, and surface analysis. The interface adsorption behaviour of the corrosion inhibitor was explored via molecular dynamics simulations. Results indicate that the minimum inhibitory concentrations (MIC) of C(12)-2-C(12) (0.021 mM) and C(14)-2-C(14) (0.005 mM) are lower than that of 1227 (0.300 mM). The results of static weightlessness measurement reveal that the corrosion inhibition effects of the three surfactants on carbon steel soaked in SRB solution follow the order of C(14)-2-C(14) > C(12)-2-C(12) > 1227, with inhibition rates of 93.23 %, 88.45 %, and 76.49 % at a concentration of 0.2 mM, respectively. The adsorption behavior of these surfactants (1227, C(12)-2-C(12), and C(14)-2-C(14)) on carbon steel surface in the presence of SRB conforms the Langmuir isotherm adsorption model. The outcomes of electrochemical experiments align with the static weight loss data. Furthermore, surface analysis results suggest that the surfactants can adsorb onto the carbon steel surface to form a protective film, thereby inhibiting SRB-induced corrosion.