Atomically-Precise Methods for Synthesis of Solid Catalysts
Synthesis of Well-defined Solid Catalysts by Surface Organometallic Chemistry
Atomically Precise Gold Catalysis
Atomically Precise Gold Nanoclusters: Synthesis and Catalytic Application
Electrochemical Atomic-level Controlled Syntheses of Electrocatalysts for the Oxygen Reduction Reaction
Preparation and Characterization of Model Catalysts for the HCl Oxidation Reaction
Controllable Synthesis of Metal Nanoparticles for Electrocatalytic Activity Enhancement
Investigating Nano-structured Catalysts at the Atomic scale by Field Ion Microscopy and Atom Probe Tomography
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- 12 Nov 2014
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About this book
There is much interest in preparing catalysts with specific structures for a desired catalytic activity. Although there has been a great amount of research into correlating particles sizes and microstructure to catalytic activity, knowledge about practical catalysts still remain ill-defined. The current challenge is now to understand atomic control.
Atomically-Precise Methods for Synthesis of Solid Catalysts provides an overview of recent developments in heterogeneous catalysts preparation which aim at controlling the microstructure of such catalysts at the atomic scale. Each chapter provides a different synthetic approach to achieve atomic-scale control along techniques to characterize the atomically-precise solids. Topics covered include bimetallic supported catalysts from single-source precursors zeolite-supported molecular metal complex catalyst, surface organometallic chemistry, atomic layer deposition and electron microscopy of catalysts.
Edited by active researchers in the area, the book aims to bridge the gap between surface science and heterogeneous catalysis. The book is suitable for graduate students as well as researchers in academia in industry from various disciplines including engineering, inorganic/organometallic chemistry, surface science and physical chemistry interested in catalyst design.