The aim of this book is the pedagogical exploration of the basic principles of quantum-statistical thermodynamics as applied to various states of matter – ranging from rare gases to astrophysical matter with high-energy density. The reader will learn in this work that thermodynamics and quantum statistics are still the concepts on which even the most advanced research is operating - despite of a flood of modern concepts, classical entities like temperature, pressure, energy and entropy are shown to remain fundamental. The physics of gases, plasmas and high-energy density matter is still a growing field and even though solids and liquids dominate our daily life, more than 99 percent of the visible Universe is in the state of gases and plasmas and the overwhelming part of matter exists at extreme conditions connected with very large energy densities, such as in the interior of stars. This text, combining material from lectures and advanced seminars given by the authors over many decades, is a must-have introduction and reference for both newcomers and seasoned researchers alike.
Most of the matter in our universe is in a gaseous or plasma state. Yet, most textbooks on quantum statistics focus on examples from and applications in condensed matter systems, due to the prevalence of solids and liquids in our day-to-day lives. In an attempt to remedy that oversight, this book consciously focuses on teaching the subject matter in the context of (dilute) gases and plasmas, while aiming primarily at graduate students and young researchers in the field of quantum gases and plasmas for some of the more advanced topics. The majority of the material is based on a two-semester course held jointly by the authors over many years, and has benefited from extensive feedback provided by countless students and co-workers. The book also includes many historical remarks on the roots of quantum statistics: firstly because students appreciate and are strongly motivated by looking back at the history of a given field of research, and secondly because the spirit permeating this book has been deeply influenced by meetings and discussions with several pioneers of quantum statistics over the past few decades.
This thoroughly updated version of the German authoritative work on self-organization has been completely rewritten by internationally renowned experts and experienced book authors to also include a review of more recent literature. It retains the original enthusiasm and fascination surrounding thermodynamic systems far from equilibrium, synergetics, and the origin of life, representing an easily readable book and tutorial on this exciting field. The book is unique in covering in detail the experimental and theoretical fundamentals of self-organizing systems as well as such selected features as random processes, structural networks and multistable systems, while focusing on the physical and theoretical modeling of natural selection and evolution processes. The authors take examples from physics, chemistry, biology and social systems, and include results hitherto unpublished in English. The result is a one-stop resource relevant for students and scientists in physics or related interdisciplinary fields, including mathematical physics, biophysics, information science and nanotechnology.
This book presents both the fundamentals and the major research topics in statistical physics of systems out of equilibrium. It summarizes different approaches to describe such systems on the thermodynamic and stochastic levels, and discusses a variety of areas including reactions, anomalous kinetics, and the behavior of self-propelling particles.
This is a book about the physical processes in reacting complex molecules, particularly biomolecules. In the past decade scientists from different fields such as medicine, biology, chemistry and physics have collected a huge amount of data about the structure, dynamics and functioning of biomolecules. Great progress has been achieved in exploring the structure of complex molecules. However, there is still a lack of understanding of the dynamics and functioning of biological macromolecules. In particular this refers to enzymes, which are the basic molecular machines working in living systems. This book contributes to the exploration of the physical mechanisms of these processes, focusing on critical aspects such as the role of nonlinear excitations and of stochastic effects. An extensive range of original results has been obtained in the last few years by the authors, and these results are presented together with a comprehensive survey of the state of the art in the field.
This is a book about the physical processes in reacting complex molecules, particularly biomolecules. In the past decade scientists from different fields such as medicine, biology, chemistry and physics have collected a huge amount of data about the structure, dynamics and functioning of biomolecules. Great progress has been achieved in exploring the structure of complex molecules. However, there is still a lack of understanding of the dynamics and functioning of biological macromolecules. In particular this refers to enzymes, which are the basic molecular machines working in living systems. This book contributes to the exploration of the physical mechanisms of these processes, focusing on critical aspects such as the role of nonlinear excitations and of stochastic effects. An extensive range of original results has been obtained in the last few years by the authors, and these results are presented together with a comprehensive survey of the state of the art in the field.
This thoroughly updated version of the German authoritative work on self-organization has been completely rewritten by internationally renowned experts and experienced book authors to also include a review of more recent literature. It retains the original enthusiasm and fascination surrounding thermodynamic systems far from equilibrium, synergetics, and the origin of life, representing an easily readable book and tutorial on this exciting field. The book is unique in covering in detail the experimental and theoretical fundamentals of self-organizing systems as well as such selected features as random processes, structural networks and multistable systems, while focusing on the physical and theoretical modeling of natural selection and evolution processes. The authors take examples from physics, chemistry, biology and social systems, and include results hitherto unpublished in English. The result is a one-stop resource relevant for students and scientists in physics or related interdisciplinary fields, including mathematical physics, biophysics, information science and nanotechnology.
The aim of this book is the pedagogical exploration of the basic principles of quantum-statistical thermodynamics as applied to various states of matter – ranging from rare gases to astrophysical matter with high-energy density. The reader will learn in this work that thermodynamics and quantum statistics are still the concepts on which even the most advanced research is operating - despite of a flood of modern concepts, classical entities like temperature, pressure, energy and entropy are shown to remain fundamental. The physics of gases, plasmas and high-energy density matter is still a growing field and even though solids and liquids dominate our daily life, more than 99 percent of the visible Universe is in the state of gases and plasmas and the overwhelming part of matter exists at extreme conditions connected with very large energy densities, such as in the interior of stars. This text, combining material from lectures and advanced seminars given by the authors over many decades, is a must-have introduction and reference for both newcomers and seasoned researchers alike.
The purpose of coding theory is the design of efficient systems for the transmission of information. The mathematical treatment leads to certain finite structures: the error-correcting codes. Surprisingly problems which are interesting for the design of codes turn out to be closely related to problems studied partly earlier and independently in pure mathematics. In this book, examples of such connections are presented. The relation between lattices studied in number theory and geometry and error-correcting codes is discussed. The book provides at the same time an introduction to the theory of integral lattices and modular forms and to coding theory.Das Ziel der Codierungstheorie ist der Entwurf eines effektiven Transformierungssystems für Informationen. Die mathematische Behandlung führt zu bestimmten endlichen Strukturen: fehlerkorrigierende Codes. Überraschenderweise stellt sich heraus, daß Zusammenhänge, die für den Entwurf solcher Codes interessant sind, eng mit Problemen, die zuvor und unabhängig davon in der Reinen Mathematik studiert wurden, verwandt sind. Dieses Buch handelt von einem Beispiel für eine solche Verwandtschaft: die von Codes und Gittern. Gitter werden in der Zahlentheorie und in der Zahlengeometrie studiert. Viele Probleme in bezug auf Codes haben ihr Gegenstück in Gittern und Kugelpackungen.
An in-depth investigation of traditional European folk medicine and the healing arts of witches • Explores the outlawed “alternative” medicine of witches suppressed by the state and the Church and how these plants can be used today • Reveals that female shamanic medicine can be found in cultures all over the world • Illustrated with color and black-and-white art reproductions dating back to the 16th century Witch medicine is wild medicine. It does more than make one healthy, it creates lust and knowledge, ecstasy and mythological insight. In Witchcraft Medicine the authors take the reader on a journey that examines the women who mix the potions and become the healers; the legacy of Hecate; the demonization of nature’s healing powers and sensuousness; the sorceress as shaman; and the plants associated with witches and devils. They explore important seasonal festivals and the plants associated with them, such as wolf’s claw and calendula as herbs of the solstice and alder as an herb of the time of the dead--Samhain or Halloween. They also look at the history of forbidden medicine from the Inquisition to current drug laws, with an eye toward how the sacred plants of our forebears can be used once again.
Combining the fields of phraseology and contrastive analysis, this book describes how patterns, defined as recurrent word-combinations with semantic unity, behave cross-linguistically. As the contrastive approach adopted in the book relies on translations and a bidirectional corpus model, the first part offers an in-depth discussion of contrastive linguistics, with special emphasis on using translations as tertium comparationis and a parallel corpus as the main source of material. Central to the contrastive analysis is the use of corpus-linguistic methods in the identification of patterns, while a deeper understanding of the phraseological nature of the patterns is closely related to the concept of extended units of meaning. The second part of the book presents five case studies, using an easy-to-follow step-by-step method to illustrate the phraseological-contrastive approach at work. The studies show that patterns weave an intricate web of meanings across languages and demonstrate the potential of exploring patterns in contrast.
An examination of the sacred botany and the pagan origins and rituals of Christmas • Analyzes the symbolism of the many plants associated with Christmas • Reveals the shamanic rituals that are at the heart of the Christmas celebration The day on which many commemorate the birth of Christ has its origins in pagan rituals that center on tree worship, agriculture, magic, and social exchange. But Christmas is no ordinary folk observance. It is an evolving feast that over the centuries has absorbed elements from cultures all over the world--practices that give plants and plant spirits pride of place. In fact, the symbolic use of plants at Christmas effectively transforms the modern-day living room into a place of shamanic ritual. Christian Rätsch and Claudia Müller-Ebeling show how the ancient meaning of the botanical elements of Christmas provides a unique view of the religion that existed in Europe before the introduction of Christianity. The fir tree was originally revered as the sacred World Tree in northern Europe. When the church was unable to drive the tree cult out of people’s consciousness, it incorporated the fir tree by dedicating it to the Christ child. Father Christmas in his red-and-white suit, who flies through the sky in a sleigh drawn by reindeer, has his mythological roots in the shamanic reindeer-herding tribes of arctic Europe and Siberia. These northern shamans used the hallucinogenic fly agaric mushroom, which is red and white, to make their soul flights to the other world. Apples, which figure heavily in Christmas baking, are symbols of the sun god Apollo, so they find a natural place at winter solstice celebrations of the return of the sun. In fact, the authors contend that the emphasis of Christmas on green plants and the promise of the return of life in the dead of winter is just an adaptation of the pagan winter solstice celebration.
This doctoral thesis explains the synthesis and characterization of novel, smart hybrid nanomaterials. Bastian Ebeling combines in this work synthetic polymers with inorganic nanoparticles from silica or gold. The first chapters offer a comprehensive introduction to basics of polymer science and the applied methodologies. In following chapters, the author describes in detail how he systematically tailored the polymers using reversible addition-fragmentation chain transfer polymerization (RAFT) for combination with inorganic nanoparticles. This work also unravels mechanistic, thermodynamic, and structural aspects of all building blocks and reaction steps. The method described here is simple to perform and opens up pathways to new sets of nanohybrid materials with potential applications as sensors, in energy conversion, or catalysis. Readers will find a unique picture of the step-by step formation of new complex nanomaterials. It offers polymer scientists a systematic guide to the formation and synthesis of a new class of responsive nanomaterials.
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