1 |
Selective catalytic reduction of NO by NH3 with WO3-TiO2 catalysts: Influence of catalyst synthesis method He YY, Ford ME, Zhu MH, Liu QC, Wu ZL, Wachs IE Applied Catalysis B: Environmental, 188, 123, 2016 |
2 |
Hydrogen production from low temperature WGS reaction on co-precipitated Cu-CeO2 catalysts: An optimization of Cu loading Jeong DW, Na HS, Shim JO, Jang WJ, Roh HS, Jung UH, Yoon WL International Journal of Hydrogen Energy, 39(17), 9135, 2014 |
3 |
Low-temperature water-gas shift reaction over supported Cu catalysts Jeong DW, Jang WJ, Shim JO, Han WB, Roh HS, Jung UH, Yoon WL Renewable Energy, 65, 102, 2014 |
4 |
The effect of preparation method on the catalytic performance over superior MgO-promoted Ni-Ce0.8Zr0.2O2 catalyst for CO2 reforming of CH4 Jeong DW, Jang WJ, Shim JO, Roh HS, Son IH, Lee SJ International Journal of Hydrogen Energy, 38(31), 13649, 2013 |
5 |
Kinetic studies of carbon nanofibre and hydrogen evolution via ethane decomposition over fresh and steam regenerated Ni/La2O3 catalyst Setayesh SR, Waugh KC Applied Catalysis A: General, 417, 174, 2012 |
6 |
Kinetic study of CO hydrogenation over co-precipitated iron-nickel catalyst Mirzaei AA, Kiai RM, Atashi H, Arsalanfar M, Shahriari S Journal of Industrial and Engineering Chemistry, 18(4), 1242, 2012 |
7 |
Synthesis and characterization of high tap-density layered Li[Ni1/3Co1/3Mn1/3]O-2 cathode material via hydroxide co-precipitation Luo XF, Wang XY, Liao L, Gamboa S, Sebastian PJ Journal of Power Sources, 158(1), 654, 2006 |
8 |
Co-precipitated copper zinc oxide catalysts for ambient temperature carbon monoxide oxidation: effect of precipitate aging atmosphere on catalyst activity Mirzaei AA, Shaterian HR, Taylor SH, Hutchings GJ Catalysis Letters, 87(3-4), 103, 2003 |
9 |
Surface chemistry of acetone on metal oxides: IR observation of acetone adsorption and consequent surface reactions on silica-alumina versus silica and alumina Zaki MI, Hasan MA, Al-Sagheer FA, Pasupulety L Langmuir, 16(2), 430, 2000 |