Lin, Y.-G.Y.-G.LinHsu, Y.-K.Y.-K.HsuChen, S.-Y.S.-Y.ChenChen, L.-C.L.-C.ChenChen, K.-H.K.-H.Chen2020-06-182020-06-18201009599428https://scholars.lib.ntu.edu.tw/handle/123456789/503312We report the use of oxygen vacancy-rich CuO-ZnO inverse opals to strikingly enhance the performance of catalytic methanol reforming reaction with a ratio of 1:0.125:1 (H2O/O2/MeOH) at a low reaction temperature of only 230 °C, yielding complete conversion of methanol, high hydrogen production rate, ultralow CO formation, and outstanding stability. © 2010 The Royal Society of Chemistry.[SDGs]SDG7CO formation; Hydrogen production rate; Inverse opal; Methanol reforming; Micro-reformers; Reaction temperature; ZnO; Hydrogen production; Methanol; Oxygen; Oxygen vacancies; Reforming reactions; Silicate minerals; Zinc oxide; Low temperature productionjournal article10.1039/c0jm02605k