| 1 |
Identification of the OH groups responsible for kinetic basicity on MgO surfaces by H-1 MAS NMR
Chizallet C, Petitjean H, Costentin G, Lauron-Pernot H, Maquet J, Bonhomme C, Che M
Journal of Catalysis, 268(1), 175, 2009 |
| 2 |
Insight into the reaction mechanism of the conversion of methylbutynol on silica-alumina
AlSawalha M, Roessner F
Reaction Kinetics and Catalysis Letters, 94(1), 63, 2008 |
| 3 |
Evaluation of surface acido-basic properties of inorganic-based solids by model catalytic alcohol reaction networks
Lauron-Pernot H
Catalysis Reviews-Science and Engineering, 48(3), 315, 2006 |
| 4 |
Influence of phosphonation and phosphation on surface acid-base and morphological properties of CaO as investigated by in situ FTIR spectroscopy and electron microscopy
Zaki MI, Knozinger H, Tesche B, Mekhemer GAH
Journal of Colloid and Interface Science, 303(1), 9, 2006 |
| 5 |
A spectroscopy and catalysis study of the nature of active sites of MgO catalysts: Thermodynamic Bronsted basicity versus reactivity of basic sites
Bailly ML, Chizallet C, Costentin G, Krafft JM, Lauron-Pernot H, Che M
Journal of Catalysis, 235(2), 413, 2005 |
| 6 |
Characterization of CrAPO-5 materials in test reactions of conversion of 2-methyl-3-butyn-2-ol and isopropanol
Zadrozna G, Souvage E, Kornatowski J
Journal of Catalysis, 208(2), 270, 2002 |
| 7 |
A spectroscopic investigation of isopropanol and methylbutynol as infrared reactive probes for base sites on polycrystalline metal oxide surfaces
Hasan MA, Zaki MI, Pasupulety L
Journal of Molecular Catalysis A-Chemical, 178(1-2), 125, 2002 |
| 8 |
Characterisation of the basicity of modified MgO-catalysts
Thomasson P, Tyagi OS, Knozinger H
Applied Catalysis A: General, 181(1), 181, 1999 |
