The papers contained in this volume were presented at the Nobel Symposium which marked the eightieth anniversary of the first award of the Nobel prizes in 1901. Leading scholars from many different fields of science and technology exchange viewpoints across interdisciplinary boundaries. Participants were chosen for their special knowledge of science and technology in the late nineteenth and early twentieth centuries and papers cover the period from the 1860s to the outbreak of the First World War.
Semiconductors and the Information Revolution sets out to explain the development of modern electronic systems and devices from the viewpoint of the semiconductor materials (germanium, silicon, gallium arsenide and many others) which made them possible. It covers the scientific understanding of these materials and its intimate relationship with their technology and many applications. It began with Michael Faraday, took off in a big way with the invention of the transistor at Bell Labs in 1947 and is still burgeoning today. It is a story to match any artistic or engineering achievement of man and this is the first time it has been presented in a style suited to the non-specialist. It is written in a lively, non-mathematical style which brings out the excitement of discovery and the fascinating interplay between the demands of system pull and technological push. It also looks at the nature of some of the personal interactions which helped to shape the modern technological world. An introductory chapter illustrates just how dependent we are on modern electronic systems and explains the significance of semiconductors in their development. It also provides, in as painless a way as possible, a necessary understanding of semiconductor properties in relation to these applications. The second chapter takes up the historical account and ends with some important results emerging from the Second World War – including its effect on the organisation of scientific research. Chapter three describes the world-shaking discovery of the transistor and some of the early struggles to make it commercially viable, including the marketing of the first transistor radio. In chapter four we meet the integrated circuit which gave shape to much of our modern life in the form of the personal computer (and which gave rise to a famously long-running patent war!). Later chapters cover the application of compound semiconductors to light-emitting devices, such as LEDs and lasers, and light detecting devices such as photocells. We learn how these developments led to the invention of the CD player and DVD recorder, how other materials were applied to the development of sophisticated night vision equipment, fibre optical communications systems, solar photovoltaic panels and flat panel displays. Similarly, microwave techniques essential to our modern day love of mobile phoning are seen to depend on clever materials scientists who, not for the first time, "invented" new semiconductors with just the right properties. Altogether, it is an amazing story and one which deserves to be more widely known. Read this book and you will be rewarded with a much deeper understanding and appreciation of the technological revolution which shapes so many aspects of our lives.
Reviving the Living: Meaning Making in Living Systems presents a novel perspective that relates to current biological knowledge and issues. Written by polymath Dr. Yair Neuman, the book challenges the dogmas that frame our understanding of living systems and presents a radical alternative approach to understanding the world around us, one that avoids the pitfalls of non-scientific perspectives such as Vitalism and Creationism. In this thought provoking and iconoclastic manuscript, Neuman follows the footsteps of Gregory Bateson, Mikhail Bakhtin, Michael Polanyi and others, to suggest that living systems are meaning making systems. The book delves into the unique processes of meaning making that characterize organisms as a unique category of nature, and offers new and fascinating insights into a variety of enigmatic biological phenomena from immune memory to hidden life (cryptobiosis). It consists of four parts divided into 18 chapters and covers topics ranging from reductionism and its pitfalls to genetics; why organisms are irreducible; immunology; meaning making in language and biology; meaning-bridging the gap between physics and semantics; context and memory; and the poetry of living. Core concepts and themes are illustrated using examples based in current science. This text would be of high interest to biologists, philosophers, cognitive scientists, psychologists, and semioticians, as well as to any reflective individual who is willing to examine the realm of the living from a novel and fascinating perspective.
Jeff’s Views provide witty, insightful, and thought-provoking looks into the life of a modern scientist. From starting off to letting go, Gottfried (“Jeff”) Schatz leads us through the trials and triumphs of scientific life. With his tongue firmly in his cheek, and his humour always intact, the Austrian essayist leads us through the confusing and seemingly insurmountable hill that is the career path of European scientists. In addition to giving useful insights into how to get funding, give seminars, and still find time to make that leading edge scientific discovery, Jeff explores the philosophical dimensions of recent biological breakthroughs such as the sequencing of the human genome, the evolution of sensory receptors, and cellular suicide. Gottfried Schatz is one of the world’s leading scientists in the field of bioenergetics and mitochondria biology. Born in a small Austrian village, he started his scientific career at the University of Graz, and ended it as President of the Swiss Science and Technology Council. With stints as a violinist in Austrian opera houses, professorships in the USA and Switzerland, and numerous prestigious awards along the way, Jeff is a true European, whose unique, and often controversial, viewpoints are appreciated by scientists and politicians alike. These essays look at science from a very personal angle – often critical, sometimes sad, but always with excitement, wonder, and admiration. It is hoped that they will make you look at science with a slightly different view.
Edited by Daniel Rothbart of George Mason University in Virginia, this book is a collection of Rom Harré's work on modeling in science (particularly physics and psychology). In over 28 authored books and 240 articles and book chapters, Rom Harré of Georgetown University in Washington, DC is a towering figure in philosophy, linguistics, and social psychology. He has inspired a generation of scholars, both for the ways in which his research is carried out and his profound insights. For Harré, the stunning discoveries of research demand a kind of thinking that is found in the construction and control of models. Iconic modeling is pivotal for representing real-world structures, explaining phenomena, manipulating instruments, constructing theories, and acquiring data.This volume in the new Elsevier book series Studies in Multidisciplinarity includes major topics on the structure and function of models, the debates over scientific realism, explanation through analogical modeling, a metaphysics for physics, the rationale for experimentation, and modeling in social encounters.
In this book, fifteen authors from a wide spectrum of disciplines (ranging from the natural sciences to the arts) offer assessments of the way time enters their work, the definition and uses of time that have proved most productive or problematic, and the lessons their subjects can offer for our understanding of time beyond the classroom and laboratory walls. The authors have tried, without sacrificing analytical rigour, to make their contribution accessible to a cross-disciplinary readership.Each chapter reviews time's past and present application in its respective field, considers the practical and logical problems that remain, and assesses the methods researchers are using to escape or resolve them. Particular attention is paid to ways in which the technical treatment of time, for problem-solving and model-building around specific phenomena, call on - or clash with - our intuitive perceptions of what time is and does. The spans of time considered range from the fractions of seconds it takes unstable particles to disintegrate to the millions of years required for one species to give way to another. Like all central conceptual words, time is understood on several levels. By inviting input from a broad range of disciplines, the book aims to provide a fuller understanding of those levels, and of the common ground that lurks at their base. Much agreement emerges - not only on the nature of the problems time presents to modern intellectual thought, but also on the clues that recent discoveries may offer towards possible solutions.
History of Analytical Chemistry is a systematic account of the historical development of analytical chemistry spanning about 4,000 years. Many scientists who have helped to develop the methods of analytical chemistry are mentioned. Various methods of analysis are discussed, including electrogravimetry, optical methods, electrometric analysis, radiochemical analysis, and chromatography. This volume is comprised of 14 chapters and begins with an overview of analytical chemistry in ancient Greece, the origin of chemistry, and the earliest knowledge of analysis. The next chapter focuses on analytical chemistry during the Middle Ages, with emphasis on alchemy. Analytical knowledge during the period of iatrochemistry and the development of analytical chemistry during the phlogiston period are then examined. Subsequent chapters deal with the development of the fundamental laws of chemistry, including the principle of the indestructibility of matter; analytical chemistry during the period of Berzelius; and developments in qualitative and gravimetric analysis. Elementary organic analysis is also considered, along with the development of the theory of analytical chemistry. This book will be helpful to chemists as well as students and researchers in the field of analytical chemistry.