Reprint
Advanced Strategies for Catalyst Design
Edited by
April 2021
202 pages
- ISBN978-3-0365-0556-5 (Hardback)
- ISBN978-3-0365-0557-2 (PDF)
This is a Reprint of the Special Issue Advanced Strategies for Catalyst Design that was published in
Chemistry & Materials Science
Engineering
Summary
The invention of novel and improved catalysts has a valuable impact on human activities and on our planet. Efficient catalysts are expected to be stable, active, and selective. In the past, the development of new catalysts has mainly depended on trial and error, a laborious and time-consuming approach. Nowadays, the mechanistic details of numerous important chemical reactions have been unraveled, and this information is useful for intelligently design novel catalysts. Thus, all the efforts devoted to facilitating a deep understanding of intricate catalytic mechanisms and to the preparation of novel catalysts relying on this are priceless. Chemists must set up adequate strategies, merging experimental and computational knowledge and abilities toward tuning the performance of molecules that might be successful in the lab. The contributions in this book collection are some examples of this modern chemical design.
Format
- Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
sulfur-tolerance; Pd4S; catalytic oxidation of methane; sulfur poisoning; acetylene [2+2+2] cycloadditions; DFT calculations; rhodium; chromium; half-sandwich catalysts; turnover frequency (TOF); activation strain analysis; indenyl effect; metal slippage; slippage span model; graphene oxide; 3-aminopropyltrimethoxysilane; heterogeneous catalyst; asymmetric epoxidation; Diels–Alder reaction; 22-carbon tricarboxylic acid; iodine; 1H-NMR; ESI-MS; transesterification; catalysis; acidity; waste cooking oil; biodiesel; iron catalyst; organogermyl ligand; reduction; dehydrogenation; core-shell structure; αMnO2 nanorods; elemental mercury removal; SO2 resistance; asymmetric conjugate addition; cinchona alkaloid catalysis; cyanation reaction of olefin; self-assembly Ti(IV)-catalysis; density functional theory calculation; contact glow discharge electrolysis; electrochemical plasma; water treatment; glycerol; H2–C3H8–SCR–NO; PtAg/Al2O3; bimetallic clusters; Al2O3–WOx; vinyl chloride monomer; acetylene hydrochlorination; mercury-free catalysts; noble metal catalyst; non-noble metal catalyst; non-metallic catalysts; n/a