Produktdetaljer
Biografisk notat
David Allan Atwood was born in 1965 in Urbana Illinois. At an early age David moved to Tuscaloosa Alabama where he grew up and ultimately attended college. After graduation from the University of Alabama he moved to Austin Texas to attend graduate school at the University of Texas with Richard Jones as his advisor. He graduated with his PhD (in Inorganic Chemistry) in the Spring of 1992 but stayed in Austin as a postdoctoral associate with Alan Cowley until his wife, Vicki Ossink Atwood, finished her PhD (also in Inorganic Chemistry). From UT he moved as an Assistant Professor to North Dakota State University as part of their new Center for Main Group Chemistry (of which he was co-director). In 1998 David Atwood joined the chemistry department at the University of Kentucky faculty as an Associate Professor. He now has over 160 publications, 10 patents, and serves on numerous editorial boards, including the Encyclopedia of Inorganic Chemistry, a 10 volume set published in Fall 2005. He is the founding editor and editor-in-chief of Main Group Chemistry. His research interests include detection and removal of heavy metal contaminants such as mercury, cadmium and lead, from the environment, the preparation of nanoparticulate metal oxides, prevention of aluminum alloy oxidation, and the synthesis of new Lewis acid compounds to effect new reactions, such as the breaking of phosphate esters bonds like those found in nerve gas agents and pesticides and the destruction of methyl-t-butyl ether (MTBE) a widespread water contaminant.
<p>“In conclusion this is a valuable book, spanning the under-graduate / postgraduate divide, which should find a place particularly in the collections of those who teach lanthanide chemistry and new researchers to the field who want to discover the remarkable scope of modern lanthanide chemistry and its exciting applications. One could not expect much more in a single volume.” (<i>Applied Organometal Chemistry</i>, 1 May 2013)</p> <p> </p> <p> </p>
Lanthanides are of great importance for the electronic industries, this new book (from the EIBC Book Series) provides a comprehensive coverage of the basic chemistry, particularly inorganic chemistry, of the lanthanoid elements, those having a 4f shell of electrons. A chapter is describing the similarity of the Group 3 elements, Sc, Y, La, the group from which the lanthanoids originate and the group 13 elements, particularly aluminum, having similar properties. Inclusion of the group 3 and 13 elements demonstrates how the lanthanoid elements relate to other, more common, elements in the Periodic Table. Beginning chapters describe the occurrence and mineralogy of the elements, with a focus on structural features observed in compounds described in later chapters. The majority of the chapters is organized by the oxidation state of the elements, Ln(0), Ln(II), Ln(III), and Ln(IV). Within this organization the chapters are further distinguished by type of compound, inorganic (oxides and hydroxides, aqueous speciation, halides, alkoxides, amides and thiolates, and chelates) and organometallic. Concluding chapters deal with diverse and critically important applications of the lanthanoids in electronic and magnetic materials, and medical imaging.
Contributors xi
Series Preface xv
Volume Preface xvii
Geology, Geochemistry, and Natural Abundances of the Rare Earth Elements 1
Scott M. McLennan and Stuart Ross Taylor
Sustainability of Rare Earth Resources 21
David A. Atwood
The Electronic Structure of the Lanthanides 27
Ana de Bettencourt-Dias
Variable Valency 35
Andrew W. G. Platt
Group Trends 43
Andrew W. G. Platt
Solvento Complexes of the Lanthanide Ions 55
Simon A. Cotton and Jack M. Harrowfield
Lanthanides in Living Systems 65
Simon A. Cotton and Jack M. Harrowfield
Lanthanides: Coordination Chemistry 73
Simon A. Cotton and Jack M. Harrowfield
Organometallic Chemistry Fundamental Properties 83
Stephen T. Liddle
Lanthanides: “Comparison to 3d Metals” 105
Simon A. Cotton
Luminescence 111
Julien Andres and Anne-Sophie Chauvin
Lanthanides: Luminescence Applications 135
Julien Andres and Anne-Sophie Chauvin
Magnetism 153
Bing-Wu Wang and Song Gao
The Divalent State in Solid Rare Earth Metal Halides 161
Gerd Meyer
Lanthanide Halides 175
Timothy J. Boyle and Leigh Anna M. Steele
Lanthanide Oxide/Hydroxide Complexes 183
Zhiping Zheng
Lanthanide Alkoxides 197
Timothy J. Boyle and Leigh Anna M. Steele
Rare Earth Siloxides 205
Clemens Krempner and Brian McNerney
Thiolates, Selenolates, and Tellurolates 215
John G. Brennan
Carboxylate 225
Jia-sheng Lu and Ruiyao Wang
Lanthanide Complexes with Amino Acids 237
Zhiping Zheng
β-Diketonate 249
Ke-Zhi Wang
Rare Earth Borides, Carbides and Nitrides 263
Takao Mori
Lanthanide Complexes with Multidentate Ligands 281
Xiaoping Yang, Richard A. Jones and Wai-Kwok Wong
Alkyl 299
Simon A. Cotton
Aryls 303
Simon A. Cotton
Trivalent Chemistry: Cyclopentadienyl 307
Roman A. Kresinski
Tetravalent Chemistry: Inorganic 313
Farid M. A. Sroor and Frank T. Edelmann
Tetravelent Chemistry: Organometallic 321
Farid M. A. Sroor and Frank T. Edelmann
Molecular Magnetic Materials 335
Bing-Wu Wang and Song Gao
Near-Infrared Materials 347
Lining Sun and Liyi Shi
Superconducting Materials 371
Antonio J. Dos santos-Garcia, Miguel Á. Alario-Franco and Regino Sáez-Puche
Metal-Organic Frameworks 385
John Hamilton Walrod II and David A. Atwood
Upconversion Nanoparticles for Bioimaging Applications 389
Jiefu Jin and Wing-Tak Wong
Oxide and Sulfide Nanomaterials 405
Takuya Tsuzuki
Rare Earth Metal Cluster Complexes 415
Gerd Meyer
Organic Synthesis 437
Yuichiro Mori and Shũ Kobayashi
Homogeneous Catalysis 459
Yingming Yao and Kun Nie
Heterogeneous Catalysis 475
John Hamilton Walrod II and David A. Atwood
Supramolecular Chemistry: from Sensors and Imaging Agents to Functional Mononuclear and Polynuclear Self-Assembly Lanthanide Complexes 481
Jonathan A. Kitchen and Thorfinnur Gunnlaugsson
Endohedral Fullerenes 495
Daniel L. Burriss and David A. Atwood
Lanthanide Shift Reagents 501
Carlos F. G. C. Geraldes
Lanthanides: Magnetic Resonance Imaging 521
Sophie Laurent, Luce Vander Elst, Sebastien Boutry and Robert N. Muller
Luminescent Bioprobes 535
Anne-Sophie Chauvin
Sensors for Lanthanides and Actinides 561
Gabriela I. Vargas-Zúñiga and Jonathan L. Sessler
Index 575
Lanthanides [or Lanthanoids] are the elements with atomic numbers 57 to 71 on the Periodic Table. The sequential filling of their 4f electron shell gives them specific chemical and very unique spectroscopic properties. These elements are actually not very “rare” at all, in earth’s crust, but are usually found with many other elements. The absence or “rarity” of concentrated mineral deposits, in comparison to the more common metals, made them difficult to obtain pure in large quantities until specific mineral extraction technologies were developed. This has made the term “rare earths” less applicable in modern terms, and certainly does not accurately reflect the earth’s abundance of these elements. Nevertheless, calling the lanthanides, “rare earth” elements has persisted and the name makes the lanthanides unique among the metals on the periodic chart, a uniqueness that is actually accurate, as this book will demonstrate
This book provides a comprehensive coverage of the basic chemistry, particularly inorganic chemistry, of the Rare Earth Elements. Inclusion of Group 3 elements (Sc, Y and La) and Group 13 elements (particularly Al) demonstrates how the Lanthanides relate to transition metals and main group elements in the Periodic Table. The book begins with chapters describing the fundamentals electronic, structural, and bonding trends of the elements to provide a foundation for understanding the specific chemistry described in subsequent chapters. The bulk of the chapters are organized based on the oxidation state of the elements, and particularly, the most common trivalent state. Within this organization the chapters focus on the wide variety of lanthanide compounds that form with specific types of ligands to provide a wide range of bonding environments. The book concludes with chapters describing the wide range of solid-state materials that contain, and utilize, lanthanides, followed by chapters on important, and newly-emerging, biological applications. The arrangement and content of the chapters in the book are designed to provide a fundamental understanding of lanthanide chemistry with examples of the most recent advances in research, and the important new and future applications of the Rare Earths.
Produktdetaljer
Biografisk notat
David Allan Atwood was born in 1965 in Urbana Illinois. At an early age David moved to Tuscaloosa Alabama where he grew up and ultimately attended college. After graduation from the University of Alabama he moved to Austin Texas to attend graduate school at the University of Texas with Richard Jones as his advisor. He graduated with his PhD (in Inorganic Chemistry) in the Spring of 1992 but stayed in Austin as a postdoctoral associate with Alan Cowley until his wife, Vicki Ossink Atwood, finished her PhD (also in Inorganic Chemistry). From UT he moved as an Assistant Professor to North Dakota State University as part of their new Center for Main Group Chemistry (of which he was co-director). In 1998 David Atwood joined the chemistry department at the University of Kentucky faculty as an Associate Professor. He now has over 160 publications, 10 patents, and serves on numerous editorial boards, including the Encyclopedia of Inorganic Chemistry, a 10 volume set published in Fall 2005. He is the founding editor and editor-in-chief of Main Group Chemistry. His research interests include detection and removal of heavy metal contaminants such as mercury, cadmium and lead, from the environment, the preparation of nanoparticulate metal oxides, prevention of aluminum alloy oxidation, and the synthesis of new Lewis acid compounds to effect new reactions, such as the breaking of phosphate esters bonds like those found in nerve gas agents and pesticides and the destruction of methyl-t-butyl ether (MTBE) a widespread water contaminant.