Metal oxides incorporated into mesoporous silica nanoparticles (MSNs) have been considered as great potential catalysts for further catalytic application, due to high surface area, adequate pore size, good reusability and easy separation. With a particle size of ~100 nm, the MSNs can also be suspended in solution very well for catalysis application in liquid state. Herein, we reported a series of catalysts that are assembled by incorporation of different amounts of iron oxide species into MSNs with high dispersion by using an one-pot direct synthesis at ambient temperature. These catalysts can perform efficiently catalytic oxidation of aromatic arenes into the corresponding oxidized products with controllable selectivity under mild condition. TEM, SEM-EDX images show that iron species are highly dispersed inside the silica materials. Nitrogen adsorption-desorption isotherms demonstrate that the obtained materials exhibit large surface area (~1000 m2 g−1), and uniform pore size (2.3 nm) even though high concentration of iron species were dispersed in MSNs (16.4%). X-ray absorption spectroscopy is used to clarify the oxidation state (Fe+3) and local structure of the iron species dispersed in MSNs before and after catalytic reaction. The heterogeneous catalysts can efficiently carry out C–H bond activations of benzene to form phenol as the major product, and of toluene to form benzaldehyde and/or benzyl alcohol in sp3 C-H bond oxidation and o-, p-cresol and/or methyl-p-benzoquinone in sp2 C-H bond oxidation under mild temperature. The particle size of iron oxide confined in the silica framework can be controlled by introducing different amount of iron precursor during synthetic process. Thus, the reactions can be facilely tuned and controlled to selectively yield an sp2 or sp3 C–H bond oxidation of toluene. Moreover, these heterogeneous catalysts are robust and reuseable. They are easily separate from the reaction mixture and can be fully recovered and reused for several cycles with only small decay of activity. Several control experiments were performed to show that the catalytic oxidation is not a typical fenton-like reaction mechanism (FeII and H2O2 for hydroxyl radical). First, the formation rate of phenol is not affected at the low pH environment where the hydroxyl radical formation rate is thought to be decrease a lot. Second, we have detected no apparent effect of the radical trapping agent on the TONs or product yields of arene oxidation, indicating that there is no radical formation (such as hydroxyl radicals) in this reaction pathway Third, kinetic isotope effect (KIE) experiments were well done and shown difference to the fenton-like mechanism. Overall, we developed an effective method to synthesize a series of high dispersion Fe-MSN catalysts for difficult aromatic C-H bond oxidation and clarified that our catalytic system is not a fenton-like reaction. With the properties of high activity for C-H bond oxidation, easy separation, cheap synthesis process, we believe that the MSN-supported iron oxide catalysts have high potential for industrial application.