Catalysis with Earth-abundant Elements Editors: Uwe Schneider, Stephen Thomas
Catalytic Use of Potassium Compounds in Organic Synthesis
Recent Advances in the Stoichiometric Chemistry of Magnesium Complexes
Open Shell Iron Catalysis: Mechanistic Challenges, Approaches and Pitfalls
Accessing Low Oxidation-state Iron Catalysts; Iron-catalysed Reductive Functionalisation
Recent Aluminium Chemistry – From Al(III ) Catalysis to Significant Stoichiometric Al(I ) Reactivity
Silyliumylidenes and Silylones: Low-valent Silicon Species in Small Molecule Activation
Recent Advances in Asymmetric Catalysis by Chiral Phosphines
Subject Index
Publication details
- Print publication date
- 30 Oct 2020
- Copyright year
- 2021
- Print ISBN
- 978-1-78801-118-1
- PDF eISBN
- 978-1-78801-277-5
- ePub eISBN
- 978-1-83916-021-9
About this book
Catalysis remains a key technology in a huge number of industrial processes in the 21st century. The catalytic properties of precious metals such as platinum and palladium are well understood. However, these metals are expensive and their supply is limited. Earth-abundant elements such as iron and nickel are, as the name suggests, in plentiful supply and much cheaper to use, but research on their use in catalysis has, historically, lagged behind. As researchers and companies increasingly look for ways to reduce costs and improve the sustainability of their processes there has been a renewed interest in these earth-abundant elements.
This book presents a detailed overview of current research on the catalytic uses of the most Earth-abundant elements. Highlighting the top ten most Earth-abundant elements and their various roles in modern synthetic chemistry: s-block metals (Na, K, Mg, Ca), first-row transition metals (Ti, Mn, Fe), and p-block elements (Al, Si, P). The significant stoichiometric use of these elements, and their use as acid, base, dual, and/or redox catalysts will be discussed. It will be of use to industrial and academic researchers as well as graduate students with an interest in catalysis and sustainability.