The author presents a new philosophy of science in the grand tradition that has recently been deemed impossible. Scerri believes that science develops as a holistic entity, which is fundamentally unified even though the individuals making up the body scientific are frequently in competition among each other. He draws inspiration from a conviction that the world is essentially unified in the way that has been described by both Western and Eastern philosophers. --
In A Tale of Seven Elements, Eric Scerri presents the fascinating history of those seven elements discovered to be mysteriously "missing" from the periodic table in 1913.
In his latest book, Eric Scerri presents a completely original account of the nature of scientific progress. It consists of a holistic and unified approach in which science is seen as a living and evolving single organism. Instead of scientific revolutions featuring exceptionally gifted individuals, Scerri argues that the "little people" contribute as much as the "heroes" of science. To do this he examines seven case studies of virtually unknown chemists and physicists in the early 20th century quest to discover the structure of the atom. They include the amateur scientist Anton van den Broek who pioneered the notion of atomic number as well as Edmund Stoner a then physics graduate student who provided the seed for Pauli's Exclusion Principle. Another case is the physicist John Nicholson who is virtually unknown and yet was the first to propose the notion of quantization of angular momentum that was soon put to good use by Niels Bohr. Instead of focusing on the logic and rationality of science, Scerri elevates the role of trial and error and multiple discovery and moves beyond the notion of scientific developments being right or wrong. While criticizing Thomas Kuhn's notion of scientific revolutions he agrees with Kuhn that science is not drawn towards an external truth but is rather driven from within. The book will enliven the long-standing debate on the nature of science, which has increasingly shied away from the big question of "what is science?"
This book represents a collection of papers from one of the founders of the new Philosophy of Chemistry. It is only the second single-author collection of papers on the Philosophy of Chemistry.The author is the editor-in-chief of Foundations of Chemistry, the leading journal in the field. He has recently gained worldwide success with his book on the periodic table of the elements titled The Periodic Table: Its Story and Its Significance. This volume provides an in-depth examination of his more philosophical and historical work in this area and further afield.
This volume follows the successful book, which has helped to introduce and spread the Philosophy of Chemistry to a wider audience of philosophers, historians, science educators as well as chemists, physicists and biologists. The introduction summarizes the way in which the field has developed in the ten years since the previous volume was conceived and introduces several new authors who did not contribute to the first edition. The editors are well placed to assemble this book, as they are the editor in chief and deputy editors of the leading academic journal in the field, Foundations of Chemistry. The philosophy of chemistry remains a somewhat neglected field, unlike the philosophy of physics and the philosophy of biology. Why there has been little philosophical attention to the central discipline of chemistry among the three natural sciences is a theme that is explored by several of the contributors. This volume will do a great deal to redress this imbalance. Among the themes covered is the question of reduction of chemistry to physics, the reduction of biology to chemistry, whether true chemical laws exist and causality in chemistry. In addition more general questions of the nature of organic chemistry, biochemistry and chemical synthesis are examined by specialist in these areas.
This comprehensive volume marks a new standard in scholarship in the emerging field of the philosophy of chemistry. Philosophers, chemists, and historians of science ask some fundamental questions about the relationship between philosophy and chemistry.
What does E=mc2 really mean? What is DNA? What was the big bang? These scientific concepts have changed our perception of the world…but for many of us they remain mysteries, bits and pieces of information retained from classroom lectures but never truly understood. Now we can finally grasp the grandeur and complexity of these ideas, and their significance in our lives. Revised and updated to include the latest discoveries that are changing the way we view the world and the universe, this new edition of The Science Class You Wish You Had will take you on a journey through space and time—from the subatomic to the universal. It explains in a lively, accessible way what these milestones of scientific discovery mean and what direct impact they have on our lives today and will have in the future. For everyone interested in science, history, and biographies of extraordinary people—or anyone who wants to understand the workings of the physical world—this thorough and authoritative book is a perfect introduction to science’s most profound discoveries, and a testament to the triumph of human knowledge. Newton: Gravity and the Basic Laws of Physics Rutherford and Bohr: The Structure of the Atom Einstein: The Principle of Relativity Hubble: The Big Bang and the Formation of the Universe Darwin: Evolution and the Principle of Natural Selection Flemming and Mendel: The Cell and Genetics Watson and Crick: The Structure of the DNA Molecule
Many young Christians interested in the sciences have felt torn between two options: remaining faithful to Christ or studying science. In this concise introduction, Josh Reeves and Steve Donaldson provide both advice and encouragement for Christians in the sciences to bridge the gap between science and Christian belief and practice.
An edited volume featuring chapters on multidisciplinary aspects of the Periodic Table, particularly focusing on the history and philosophy of chemistry
Well-being, happiness and quality of life are now established objects of social and medical research. Does this science produce knowledge that is properly about well-being? What sort of well-being? The definition and measurement of these objects rest on assumptions that are partly normative, partly empirical and partly pragmatic, producing a great diversity of definitions depending on the project and the discipline. This book, written from the perspective of philosophy of science, formulates principles for the responsible production and interpretation of this diverse knowledge. Traditionally, philosophers' goal has been a single concept of well-being and a single theory about what it consists in. But for science this goal is both unlikely and unnecessary. Instead the promise and authority of the science depends on it focusing on the well-being of specific kinds of people in specific contexts. Skeptical arguments notwithstanding, this contextual well-being can be measured in a valid and credible way - but only if scientists broaden their methods to make room for normative considerations and address publicly and inclusively the value-based conflicts that inevitably arise when a measure of well-being is adopted. The science of well-being can be normative, empirical and objective all at once, provided that we line up values to science and science to values.
