This work presented a mass transfer process of absorbing toluene and isopropanol in a cross-flow rotating packed bed (RPB) at the same time. Toluene is a hydrophobic volatile organic compound (VOC) while isopropanol is a hydrophilic VOC. Water, silicone oil, as well as the mixture of silicone oil and water were used as absorbents for these absorption processes. When using water as the only absorbent, the best absorption fraction of isopropanol was 0.99, but it was only 0.1 for toluene. It obviously indicated that water is a suitable absorbent for hydrophilic VOCs. When silicone oil was the absorbent alone, the best absorption fraction for toluene was 0.78, and 0.33 for isopropanol. It suggested that silicone oil is a appropriate absorbent for hydrophobic VOCs. Then, we implemented the absorption processes of toluene and isopropanol by the mixture of silicone oil and water. Both absorption fractions for these two compounds could reach more than 0.9. We calculated the enhancement factor (E) to evaluate the impacts on absorptions of toluene and isopropanol by this mixed absorbent. As the silicone oil flow rate was 0.1, the E value of toluene rose significantly to 2.5 with increasing water flow rate. Higher the silicone oil flow rate resulted in less enhancements. However, the E value of isopropanol was less than 1 when the water flow rate were 0.01 and 0.03 L/min, and it would gradually increase to about 1 with the increase of water flow rate. The “insertive merging effect” and the total liquid flow rate effect could be used to explain the results above. The insertive merging effect means that the water droplet inserted into silicone oil droplet. This effect increased the effective gas-liquid contact area of oil but hindered that of water. Thus it was favorable for absorption of toluene but not for isopropanol. The total liquid flow rate effect means that water lead silicone oil of high viscosity to distribute better inside the RPB, and it causes higher gas-liquid contact area between toluene and silicone oil. Therefore, it could enhance mass transfer for hydrophobic VOCs.