Iron and oxalic acids are widely distributed in the atmosphere and easily form ferric oxalate complex (Fe(Ⅲ)-Ox). The tropospheric aqueous-phase could provide a medium to enable the photo-Fenton reaction with Fe(Ⅲ)-Ox under solar irradiation. Although the photolysis mechanisms of Fe(Ⅲ)-Ox have been investigated extensively, information about the oxidation of volatile organic compounds (VOC), specifically the potential for Secondary Organic Aerosol (SOA) formation in the Fe(Ⅲ)-Ox system, is lacking. In this study, a ubiquitous VOC methacrolein (MACR) is chosen as a model VOC, and the oxidation of MACR with Fe(Ⅲ)-Ox is investigated under typical atmospheric water conditions. The effects of oxalate concentration, Fe(Ⅲ) concentration, MACR concentration, and pH on the oxidation of MACR are studied in detail. Results show that the oxidation rate of MACR greatly accelerates in the presence of oxalate when compared with only Fe(Ⅲ). The oxidation rate of MACR also accelerates with increasing concentration of oxalate. The effect of Fe(Ⅲ) is found to be more complicated. The oxidation rate of MACR first increases and then decreases with increasing Fe(Ⅲ) concentration. The oxidation rate of MACR increases monotonically with decreasing pH in the common atmospheric water pH range or with decreasing MACR concentration. The production of ferrous and hydrogen peroxide, pH, and aqueous absorbance are monitored throughout the reaction process. The quenching experiments verify that ·OH and (O-·2) are both responsible for the oxidation of MACR. MACR is found to rapidly oxidize into small organic acids with higher boiling points and oligomers with higher molecular weight, which contributes to the yield of SOA. These results suggest that Fe(Ⅲ)-Ox plays an important role in atmospheric oxidation.