Diesel removal efficiency in soil washing process by mixed solution of nonionic surfactant and biosurfactant

Abstract

In this study, Tween 80 and three biosurfactant (Rhamnolipid, Saponin and Lipopeptide) were mixed to formulate the appropriate surfactant solution for diesel removal from contaminated soil by washing process. The mixed surfactant system was fixed at 5% w/v of active surfactants concentration in total with different mass ratio of Tween 80 to biosurfactant at 9:1, 8:2 and 7:3 of total concentration. The critical micelle concentration (CMC) of various ratio surfactant mixtures and their interfacial tension (IFT) with diesel were determined and compared with their individual surfactant. The results illustrate that mixed Tween and Lipopeptide at 9:1 mass ratio had the lowest IFT with 10 times lower than its individual surfactants. All mixed surfactant formulations showed the lower CMC than the individual biosurfactant, but still higher than that of Tween 80. The selected mixture of Tween 80 and Lipopeptide was investigated the influence of surfactant on TW sorption and diesel removal efficiency on various of soil texture. The mixed surfactant decreased the sorption of Tween 80 on soil compared to the system of individual TW because of the effect of charge repulsive between negative charge on mixed micelle and soil surface. The diesel removal by mixed Tween 80 and Lipopeptide was slightly lower than that of the individual TW. This might be due to the DI rinsing step, which increased the total diesel removal efficiency of single Tween 80. Moreover, the results displayed that the concentration of mixed Tween 80 and Lipopeptide could be decreased to 3% w/v (2.7% w/v of Tween 80 and 0.3% of Lipopeptide) with negligible loss of diesel removal efficiency. Besides the concentration of mixed surfactant, liquid-solid ratio (L-S ratio) and centrifuge speed were evaluated the optimal level in diesel removal efficiency by central composite rotatable design (CCRD). The results showed that surfactant concentration and L-S ratio significantly influenced on diesel removal efficiency. The highest diesel removal efficiency was 79.90 %. The predicted optimal level of surfactant concentration was approximately 3% w/v. For L-S ratio and centrifuge speed, the model suggests that these two factors could be increased for improving the diesel removal efficiency in the further study.