Abstract There are many studies investigated on the VOCs abatement and noble metal-based catalysts such as Au, Pt, Pd-catalysts show good activity. However, the industrial application of noble metal-based catalysts is limited by their price. Thus many different species of transition metals have been developed and applied in many fields. This study intends to synthesize non-noble metal catalysts via one step aerosol assisted evaporation induced self-assembly (Aero-EISA) process. Unlike conventional sol-gel or hydrothermal method which required tedious and time-consumed steps for manufacturing metal catalysts, the one step Aero-EISA process has the advantage of time-saving and can be designed as a continuous process for easy mass production. There is no report available on synthesizing metal catalysts by Aero-EISA and applying them to the destruction of VOCs. This study intends to present results on the physical and chemical characterization of metal mesoporous silica particles (metal-MSPs) by one step Aero-EISA process and further investigation for the catalytic oxidation of acetone. The results showed that Ce-MSPs is the best metal catalytst for the acetone destruction among various metals of Ce, Mn, Cu, Fe, Al-MSPs. This is because CeO2 has the ability to transport oxygen, high oxygen-storge capacity (OSC) and more oxygen available in the oxidation reaction by the Ce3+/Ce4+ redox couple state. Among the five different Ce loading amounts, Ce-MSPs(25) showed the best catalytic activity due to its relatively high specific surface area of 951 m2/g and optimal Ce metal content of 3.72 wt.%. The Ce-MSPs(10) had a higher Ce loading of 9.76 wt.%, but its smaller specific surface area of 615 m2/g, poor pore size distribution, and less-ordered pore structure resulted in a relatively lower acetone removal as compred to the Ce-MSPs(25). For tests on the monometallic Ce-MSPs(25) and bimetallic Ce/Mn, Ce/Cu, Ce/Al-MSPs under acetone concentration of 1000ppmv and gas hourly space velocity (GHSV) of 15000h-1, it was demonstrated that all of the samples had similar acetone removal efficiencies at the temperature above 250°C, which was due to the good oxidation activity of Ce metal in higher temperature range. But at low temperature of 150-200°C, the Ce/Al-MSPs had much higher acetone removals than all other cataltsts due to the good absoption ability of Al metal in lower temperature range. The synergetic effect of Ce, Al metal was observed for bimetallic Ce/Al-MSPs on the acetone removal as compared to the monometallic Ce-MSPs or Al-MSPs catalysts. The Al loading amount, specific surface area, and the CeO2 particle size played important roles on the low temperature catalytic oxidation of acetone. This study also compared the acetone oxidation efficiencies between Ce/Al-MSPs(50/25) (synthesized by one step Aero-EISA), Ce-Al-MSPs(25) (synthesized by combining the one step Aero-EISA and wet metal impregnation method) and Ce-ZSM-5 (synthesized by Ce metal wet impregnation on ZSM-5 commercial product) under 150, 200°C low temperature. The results indicated that Ce/Al-MSPs(50/25) had the best acetone oxidation performance due to the high specific surface area, uniform pore size as well as wide spread of CeO2 particles. Moreover, the highest amount of CeO2, oxygen storage capacity, oxygen vacancy and tetrahedral coordination framework Aluminum structure also resulted in the highest acetone oxidation and the best stability. The Ce/Al-MSPs(50/25) exhibited good stability of 74% acetone removal within 24h test period at 150°C and 85% acetone removal within 72h test period at 200°C. Keywords: Volatile organic compounds (VOCs); mesoporous silica materials; metal catalyst; acetone; ceria; aerosol assisted evaporation induced self-assembly (EISA) process