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With the clear writing and accessible approach that have made it the authoritative introduction to the field of molecular photosynthesis, this fully revised and updated edition now offers students and researchers cutting-edge topical coverage of bioenergy applications and artificial photosynthesis; advances in biochemical and genetic methods; as well as new analytical techniques. Chapters cover the origins and evolution of photosynthesis; carbon metabolism; photosynthetic organisms and organelles; and the basic principles of photosynthetic energy storage. The book's website includes downloadable PowerPoint slides.
Life on earth depends on the photosynthetic use of solar energy by plants, and efforts to develop alternative sources of energy include a major thrust toward the use of photosynthesis to yield fuels. The study of photosynthesis is an especially convincing way of bringing together the disciplines of physics, chemistry, and biology and can be a valuable element in the teaching of biophysics and biochemistry. This book provides the only detailed modern treatment of the subject in a concise form. Part I outlines the historical development of the subject, emphasizing the chemical nature of photosynthesis and the roles of chlorophylls and other pigments. Part II reviews our present knowledge of the structure and components of photosynthetic tissues in relation to their function. Part III deals with the photo-chemistry of photosynthesis and with the patterns of chemical events, principally electron and proton transfer, that follow the photo-chemistry. Part IV treats the relationships of electron and proton transport to ATP formation, and the metabolic patterns of carbon assimilation. An epilogue exposes major areas of confusion and ignorance and indicates potentially fruitful directions of research, including the development of photosynthetic systems for solar energy conversion. Throughout the book, there are frequent digressions into those aspects of optics and molecular physics relevant to the subject matter. Suitable for upper undergraduate and graduate course use, this book is also sufficiently detailed to give professional scientists a perspective of the subject at the level of contemporary research.
Advanced Biochemistry: A Series of Monographs: Primary Processes in Photosynthesis focuses on the processes involved in photosynthesis, including chloroplast structure, electronic spectra of polyatomic molecules, and photochemistry. The monograph first tackles the natural history of photosynthesis, photosynthetic apparatus, and radiation physics. Discussions focus on electronic spectra of polyatomic molecules, molecular spectroscopy of porphyrins and chlorophylls, chloroplast composition, individual components of the chromatophore, chloroplast structure and development, and systematics of photosynthesis. The publication then examines photochemistry, including fast reactions of excited molecules as revealed by fluorescence quenching, photochemistry of chlorophyll, two-quantum process in chloroplasts, and prospects for the biochemical era. The monograph is a valuable source of data for plant science experts and researchers interested in photosynthesis.
This landmark collective work introduces the physical, chemical, and biological principles underlying photosynthesis: light absorption, excitation energy transfer, and charge separation. It begins with an introduction to properties of various pigments, and the pigment proteins in plant, algae, and bacterial systems. It addresses the underlying physics of light harvesting and key spectroscopic methods, including data analysis. It discusses assembly of the natural system, its energy transfer properties, and regulatory mechanisms. It also addresses light-harvesting in artificial systems and the impact of photosynthesis on our environment. The chapter authors are amongst the field’s world recognized experts. Chapters are divided into five main parts, the first focused on pigments, their properties and biosynthesis, and the second section looking at photosynthetic proteins, including light harvesting in higher plants, algae, cyanobacteria, and green bacteria. The third part turns to energy transfer and electron transport, discussing modeling approaches, quantum aspects, photoinduced electron transfer, and redox potential modulation, followed by a section on experimental spectroscopy in light harvesting research. The concluding final section includes chapters on artificial photosynthesis, with topics such as use of cyanobacteria and algae for sustainable energy production. Robert Croce is Head of the Biophysics Group and full professor in biophysics of photosynthesis/energy at Vrije Universiteit, Amsterdam. Rienk van Grondelle is full professor at Vrije Universiteit, Amsterdam. Herbert van Amerongen is full professor of biophysics in the Department of Agrotechnology and Food Sciences at Wageningen University, where he is also director of the MicroSpectroscopy Research Facility. Ivo van Stokkum is associate professor in the Department of Physics and Astronomy, Faculty of Sciences, at Vrije Universiteit, Amsterdam.
MOLECULAR MECHANISMS OF PHOTOSYNTHESIS Rediscover the foremost introduction to molecular photosynthesis on the market today In the comprehensively revised Third Edition of Molecular Mechanisms of Photosynthesis, distinguished researcher and professor Robert E. Blankenship delivers a brand-new update to the most authoritative textbook on the subject of photosynthesis. In addition to thorough coverage of foundational topics in photosynthesis, the book discusses cutting-edge advances in research in this area, including new structures and new information about the mechanism of oxygen production. The author also describes advancements in the understanding of the regulation of photosynthesis and the critical process of photoprotection, as well as newly discovered pigments and organisms that extend oxygenic photosynthesis deeper into the near infrared spectral region. Readers will also benefit from the inclusion of a fulsome appendix that incorporates a detailed introduction to the physical basis of photosynthesis, including thermodynamics, kinetics, and spectroscopy. A companion website offers downloadable figures as PowerPoint slides ideal for teaching. The book also includes: Thorough introductions to the basic principles of photosynthetic energy storage, photosynthetic organisms and organelles, and the history and early development of photosynthesis An expansive discussion of photosynthetic pigments, including their structure and spectroscopy Explorations of antenna complexes, energy transfer processes, reaction centers, and electron transport pathways in anoxygenic phototrophs and oxygenic photosynthetic organisms Comprehensive treatments of chemiosmotic coupling, ATP synthesis, and carbon metabolism Authoritative discussions of the evolution of photosynthesis and artificial photosynthesis Perfect for advanced undergraduate and beginning graduate students in biochemistry and biophysics, Molecular Mechanisms of Photosynthesis will also earn a place in the libraries of students studying plant biology and seeking a one-stop resource in the field of molecular photosynthesis.
A quantum origin of life? -- Quantum mechanics and emergence -- Quantum coherence and the search for the first replicator -- Ultrafast quantum dynamics in photosynthesis -- Modelling quantum decoherence in biomolecules -- Molecular evolution -- Memory depends on the cytoskeleton, but is it quantum? -- Quantum metabolism and allometric scaling relations in biology -- Spectroscopy of the genetic code -- Towards understanding the origin of genetic languages -- Can arbitrary quantum systems undergo self-replication? -- A semi-quantum version of the game of life -- Evolutionary stability in quantum games -- Quantum transmemetic intelligence -- Dreams versus reality : plenary debate session on quantum computing -- Plenary debate: quantum effects in biology : trivial or not? -- Nontrivial quantum effects in biology : a skeptical physicists' view -- That's life! : the geometry of p electron clouds.
The volume is intended as an introduction to the physical principles governing the main processes that occur in photosynthesis, with emphasis on the light reactions and electron transport chain. A unique feature of the photosynthetic apparatus is the fact that the molecular structures are known in detail for essentially all of its major components. The availability of this data has allowed their functions to be probed at a very fundamental level to discover the design principles that have guided evolution. Other volumes on photosynthesis have tended to focus on single components or on a specific set of biophysical techniques, and the authors’ goal is to provide new researchers with an introduction to the overall field of photosynthesis. The book is divided into sections, each dealing with one of the main physical processes in photosynthetic energy conversion. Each section has several chapters each describing the role that a basic physical property, such as charge or spin, plays in governing the process being discussed. The chapters proceed in an orderly fashion from a quantum mechanical description of early processes on an ultrafast timescale to a classical treatment of electron transfer and catalysis on a biochemical timescale culminating in evolutionary principles on a geological timescale.
“Anyone who is not shocked by quantum theory has not understood it.” Since Niels Bohr said this many years ago, quantum mechanics has only been getting more shocking. We now realize that it’s not really telling us that “weird” things happen out of sight, on the tiniest level, in the atomic world: rather, everything is quantum. But if quantum mechanics is correct, what seems obvious and right in our everyday world is built on foundations that don’t seem obvious or right at all—or even possible. An exhilarating tour of the contemporary quantum landscape, Beyond Weird is a book about what quantum physics really means—and what it doesn’t. Science writer Philip Ball offers an up-to-date, accessible account of the quest to come to grips with the most fundamental theory of physical reality, and to explain how its counterintuitive principles underpin the world we experience. Over the past decade it has become clear that quantum physics is less a theory about particles and waves, uncertainty and fuzziness, than a theory about information and knowledge—about what can be known, and how we can know it. Discoveries and experiments over the past few decades have called into question the meanings and limits of space and time, cause and effect, and, ultimately, of knowledge itself. The quantum world Ball shows us isn’t a different world. It is our world, and if anything deserves to be called “weird,” it’s us.