Abstract
This review focuses on the use of homogeneous transition metal complexes for the catalytic dehydrogenation of amines for synthetic purposes, and for hydrogen storage applications. The catalytic dehydrogenation of primary, secondary and cyclic amines is reviewed looking at reaction conditions, different catalysts and common side reactions. Recent developments in this active field of research showcase how cooperative ligands and photocatalysts can overcome the need for noble metals or harsh reaction conditions.
Funding statement: The author thanks Dr Andrew Walden and Gannon Connor MSc for providing critical feedback, and The Netherlands Organization for Scientific Research for financial support (Rubicon Postdoctoral Fellowship 680-50- 1517)
About the author
Daniël Broere obtained his bachelors degree with honors in 2010 at the HU University of Applied Sciences, Utrecht. He obtained his master’s degree cum laude in 2012 at the VU University Amsterdam. Subsequently, he moved to the University of Amsterdam where he obtained his PhD in Chemistry cum laude in 2016, under supervision of Jarl Ivar van der Vlugt and Joost Reek, working on redox-active ligands. Currently, he is a postdoctoral fellow in the group of Patrick Holland at Yale University on a NWO Rubicon fellowship, and a part-time assistant professor at the Utrecht University. In September 2018, Daniel will start his own independent research group and tenure track at Utrecht University focusing on the development of well defined homogeneous multimetallic catalyst systems.
References
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