Support effect in the preparation of supported metal catalysts via microemulsion?
RSC Advances Pub Date: 2014-10-02 DOI: 10.1039/C4RA10736E
Abstract
It is well known that the activities of supported metal catalysts are strongly dependent upon the size, shape and dispersion of the nanoparticles on the support material. There are several techniques which can be implemented in order to produce such catalysts, e.g. wet impregnation, however the deposition of nanoparticles (NPs) on the support material without agglomeration still proves a challenge. This is particularly significant when attempting to maintain the size and shape of the particles during the deposition process. We have introduced a new method to deposit metal NPs, namely thermo-destabilization of microemulsions (please see J. Mater. Chem., 2012, 22, 11605–11614 and Nanoscale, 2013, 5, 796–805), in which the NPs are formed prior the deposition process. This method is an ingenious approach to control the dispersion of NPs on the support material and depositing NPs evenly with a narrow size distribution. In this paper we expound the important role of the surface charges of NPs and the support material, as indicated by zeta potentials, on the metal dispersion, and how they affect the catalytic activity. We also investigate the influence of other parameters such as the pore size and the pre-calcination of the support on the catalytic activities of the resulting supported metal catalysts.
Recommended Literature
- [1] Aluminium complexes with thio-phosphorus ligands: syntheses and characterisations of [Al2(CyPS3)2(CyPHS2)2] and [Al(S2PPh2)3]? Robert P. Davies,Maria A. Giménez,Laura Patel,Andrew J. P. WhiteDalton Trans., 2008, 5705-5707 10.1039/B813427H
- [2] An apparatus for testing water by measurement of its electrical conductivity Analyst, 1912,37, 538-543 10.1039/AN9123700538
- [3] An autonomous self-optimizing flow machine for the synthesis of pyridine–oxazoline (PyOX) ligands? Eric Wimmer,Daniel Cortés-Borda,Solène Brochard,Elvina Barré,Charlotte Truchet,Fran?ois-Xavier FelpinReact. Chem. Eng., 2019,4, 1608-1615 10.1039/C9RE00096H
- [4] Acetylcholinesterase amperometric detection system based on a cobalt(II) tetraphenylporphyrin-modified electrode Analyst, 1996,121, 1123-1126 10.1039/AN9962101123
- [5] An artificial photosynthetic system for photoaccumulation of two electrons on a fused dipyridophenazine (dppz)–pyridoquinolinone ligand? Philipp Traber,Stephan Kupfer,Stefanie Gr?fe,Isabelle Baussanne,Martine Demeunynck,Jean-Marie Mouesca,Serge Gambarelli,Vincent Artero,Murielle Chavarot-KerlidouChem. Sci., 2018,9, 4152-4159 10.1039/C7SC04348A
- [6] An investigation into the origin of variations in photovoltaic performance using D–D–π–A and D–A–π–A triphenylimidazole dyes with a copper electrolyte? Govind ReddyMol. Syst. Des. Eng., 2021,6, 779-789 10.1039/D1ME00073J
- [7] Alt-proteins: A promising future 10.1002/fsat.3701_10.x
- [8] An assay for the enzyme N-acetyl-β-d-glucosaminidase (NAGase) based on electrochemical detection using screen-printed carbon electrodes (SPCEs) R. M. Pemberton,J. P. Hart,T. T. MottramAnalyst, 2001,126, 1866-1871 10.1039/B104874K
- [9] An artificial photosynthesis system comprising a covalent triazine framework as an electron relay facilitator for photochemical carbon dioxide reduction? Siquan Zhang,Shengyao Wang,Liping Guo,Hao Chen,Bien Tan,Shangbin JinJ. Mater. Chem. C, 2020,8, 192-200 10.1039/C9TC05297F
- [10] An atomistic mechanism for the degradation of perovskite solar cells by trapped charge? Eunhak Lim,Jiyoung Heo,Seong Keun KimNanoscale, 2019,11, 11369-11378 10.1039/C9NR02193K
Journal Name:RSC Advances
research_products
-
CAS no.: 89640-58-4