Bimetallic nickel and palladium complexes for catalytic applications

Shane C Van Wyk; Martin O. Onani; Ebbe Nordlander

doi:10.1515/chempap-2016-0036

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Bimetallic nickel and palladium complexes for catalytic applications

Shane C Van Wyk , Martin O. Onani und Ebbe Nordlander

Veröffentlicht/Copyright: 31. März 2016

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Aus der Zeitschrift Chemical Papers Band 70 Heft 8

Abstract

South Africa is a mineral-rich country and one area in which minerals can be very important is catalysis. Over an extended period of time, homogeneous catalysis has grown to become very useful, particularly in the chemical and pharmaceutical industries. The organometallic compounds required in the catalysis industry have advanced from metallocenes to an alternative in the form of α-diimines. Most α-diimines are prepared from iminopyridyl moieties and are most active with nickel and palladium transition metals. This review providesa history of homogeneous catalysis and a discussion on iminopyridines, with the main focus on the nickel and palladium complexes formed from them. There follows a discussion of the bimetallic nickel and palladium complexes in various catalytic applications such as Suzuki and Heck coupling, with the main focus on ethylene polymerisation. The limitations are addressed and possible solutions presented to overcome those challenges. Several reviews in the related topics are to be found in the literature but not the α-diimine with iminopyridines and bimetallic nickel and palladium metals.

Keywords: homogeneous catalysis; α-diimine; iminopyridines; ethylene polymerisation; nickel; palladium

Acknowledgements

The author would like to thank the National Research Foundation of South Africa as well as Eurosa for the financial support received.

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Received: 2015-3-21

Revised: 2015-11-14

Accepted: 2015-12-2

Published Online: 2016-3-31

Published in Print: 2016-8-1

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Artikel in diesem Heft

https://doi.org/10.1515/chempap-2016-0036

Schlagwörter für diesen Artikel

homogeneous catalysis; α-diimine; iminopyridines; ethylene polymerisation; nickel; palladium