The Periodic Table II

1. Front Matter

   Pages i-xi

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2. The Renaissance of Base Metal Catalysis Enabled by Functional Ligands

   • Maximilian Fritz, Sven Schneider

   Pages 1-36

3. The Periodic Table, Zeolites and Single-Site Heterogeneous Catalysts

   • John Meurig Thomas

   Pages 37-52

4. Synthesis and Properties of Zeolite Materials Guided by Periodic Considerations

   • Luis Gómez-Hortigüela, Joaquín Pérez-Pariente

   Pages 53-88

5. The Periodic Table as a Guide to the Construction and Properties of Layered Double Hydroxides

   • Hong Yan, Xiao-Jie Zhao, Yu-Quan Zhu, Min Wei, David G. Evans, Xue Duan

   Pages 89-120

6. Perovskite: A Solid-State Chemistry Chameleon, Illustrating the Elements, Their Properties and Location in the Periodic Table

   • Anthony R. West

   Pages 121-152

7. The Periodic Table’s Impact on Bioinorganic Chemistry and Biology’s Selective Use of Metal Ions

   • Ambika Bhagi-Damodaran, Yi Lu

   Pages 153-173

8. A Periodic Table for Life and Medicines

   • Russell J. Needham, Peter J. Sadler

   Pages 175-201

9. Interactions Between Metal Ions and DNA

   • Christine J. Cardin

   Pages 203-237

10. Back Matter

    Pages 239-242

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As 2019 has been declared the International Year of the Periodic Table, it is appropriate that Structure and Bonding marks this anniversary with two special volumes.

In 1869 Dmitri Ivanovitch Mendeleev first proposed his periodic table of the elements. He is given the major credit for proposing the conceptual framework used by chemists to systematically inter-relate the chemical properties of the elements. However, the concept of periodicity evolved in distinct stages and was the culmination of work by other chemists over several decades. For example, Newland’s Law of Octaves marked an important step in the evolution of the periodic system since it represented the first clear statement that the properties of the elements repeated after intervals of 8. Mendeleev’s predictions demonstrated in an impressive manner how the periodic table could be used to predict the occurrence and properties of new elements. Not all of his many predictions proved to be valid, but the discovery ofscandium, gallium and germanium represented sufficient vindication of its utility and they cemented its enduring influence. Mendeleev’s periodic table was based on the atomic weights of the elements and it was another 50 years before Moseley established that it was the atomic number of the elements, that was the fundamental parameter and this led to the prediction of further elements. 

Some have suggested that the periodic table is one of the most fruitful ideas in modern science and that it is comparable to Darwin’s theory of evolution by natural selection, proposed at approximately the same time. There is no doubt that the periodic table occupies a central position in chemistry. In its modern form it is reproduced in most undergraduate inorganic textbooks and is present in almost every chemistry lecture room and classroom. 

This second volume provides chemists with an overview of the important role played by the Periodic Table in advancing our knowledge of solidstate and bioinorganic chemistry.  It also illustrates how it has been used to fine-tune the properties of compounds which have found commercial applications in catalysis, electronics, ceramics and in medicinal chemistry.  

• Photoelectron studies
• Homogenous catalyst
• Bio-inorganic Chemistry
• Periodic Tables
• Chemical Valency
• Zeolites
• d and s block elements
• metal ions
• lantanides and actinide
• Solid state Chemistry

• Inorganic Chemistry Laboratory, University of Oxford, Oxford, UK

  D. Michael P. Mingos

Michael Mingos was born in Basra, Iraq in 1944 and was educated in England (Manchester, B.Sc. in Chemistry 1965) and University of Sussex (D.Phil, 1968). He has held academic posts at QMC, Oxford (Keble College), Imperial College, St Edmund Hall (Principal,1999-2009). His theoretical research has resulted in generalisations which have greatly influenced the development and teaching of modern inorganic chemistry. Specifically the Wade-Mingos Rules which rationalise the structures of polyhedral inorganic molecules and the Green-Davies-Mingos Rules, which account for some of the nucleophilic reactions  of organometallic compounds. His group has experimentally verified some of his theoretical predictions, for example an icosahedral molecule containing gold atoms -which is relevant for understanding the metal’s nano-technological possibilities. He has also contributed to the understanding of the bonding properties of nitric oxide, an important cellular signalling molecule involved in many physiological processes and pioneered the acceleration of chemical reactions using microwave energy. He was elected the Royal Society in 1992 and the European Academy of Sciences in 2017. He holds honorary doctorates from Sussex and Manchester Universities and received many prizes – the most recent was the Blaise Pascal Medal in 2017

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