Quantifying Matter, Revised Edition explains how scientists learned to measure matter and quantify some of its most fascinating and useful properties. It presents many of the most important intellectual achievements and technical developments that led to the scientific interpretation of substance, starting with the cosmic origin of the elements. Complete with full-color photographs, this newly updated reference describes the fundamental characteristics and properties of matter. Quantifying Matter, Revised Edition is designed to help any student or teacher with an interest in the measurement and behavior of matter discover what matter is, how scientists measure and characterize its various forms, and how the properties of matter have influenced the course of human civilization. Chapters include: Exploring the Nature of Matter The Origin of Matter The Search for Substance Quantifying Matter During the Scientific Revolution Understanding Matter's Electromagnetic Properties Periodic Table of the Elements Discovering the Radioactive Nature of Matter Exploring the Atomic Nucleus Contemporary View of Matter Manipulating Matter Atom by Atom.
Core textbook showcasing the broad scope and coherence of physical chemistry Principles of Physical Chemistry introduces undergraduate students to the concepts and methods of physical chemistry, which are fundamental to all of Chemistry. In their unique approach, the authors guide students along a logically consistent pathway from the principles of quantum mechanics and molecular structure to the properties of ensembles and supramolecular machines, with many examples from biology and nanoscience. By systematically proceeding from atoms to increasingly complex forms of matter, the book elucidates the connection between recognizable paradigms and modern chemistry research in a student-friendly manner. To promote intuition and understanding for beginning students, the text introduces concepts before proceeding to more rigorous treatments. Rigorous proofs and derivations are provided, as electronic supplements, for more advanced students. The book poses over 900 exercises and problems to help the student learn and master methods for physicochemical reasoning. Computational supplementary material, including Fortran simulations, MathCAD exercises, and Mathematica programs, are included on a companion website. Some topics discussed in the text are: Electronic structure and Variational Principle, including Pauli exclusion, spin-orbit interactions, and electron confinement in quantum dots. Chemical bonding and molecular structure, including electron tunneling, comparison of electron-in-a-box models and electron orbital methods, and the mechanics of chemical bonds. Absorption and emission of light, including transition dipoles for π-electron systems, coupled chromophores, excitons, and chiroptical activity. Statistical description of molecular ensembles, including microscopic interpretations of phase transitions, entropy, work, and heat. Chemical equilibria, including statistical description of equilibrium constants, electrochemistry, and the exposition of fundamental reaction types. Reaction kinetics and reaction dynamics, including nonlinear coupled reactions, femtochemistry, and solvent effects on reactions. Physicochemical properties of macromolecules and the principles of supramolecular assemblies, including polymer dynamics and chemical control of interfaces. The logic of supramolecular machines and their manipulation of photon, electron, and nuclear motion. With its highly coherent and systematic approach to the subject, Principles of Physical Chemistry is an ideal textbook and resource for students in undergraduate physical chemistry courses, especially those in programs of study related to chemistry, engineering, and molecular and chemical biology.
University Physics: Arfken Griffing Kelly Priest covers the concepts upon which the quantitative nature of physics as a science depends; the types of quantities with which physics deals are defined as well as their nature; and the concepts of units and dimensions. The book describes the concepts of scalars and vectors; the rules for performing mathematical operations on vector quantities; the concepts of force, torque, center of gravity, and types of equilibrium. The text also describes the concepts and quantities required to describe motion; the linear kinematical relationships to describe motion; as well as the interrelationship between forces, which effect motion, and the motion itself. The concepts of mechanical work, kinetic energy and power; conservative and nonconservative forces; and the conservation of linear momentum are also considered. The book further tackles the concept of the center of mass; the rotational analogs of translational dynamics; and the mechanics of rotating systems. The text then demonstrates the motion of a rigid body; oscillatory motion, the mechanical properties of matter; and hydrodynamics. Thermodynamics, electricity, electromagnetism, and geometric and physical optics are also encompassed. Quantum and nuclear physics are also looked into. Students taking physics courses will find the book useful.
This book studies the fundamental concept of hydrodynamics as part of theoretical physics and demonstrates the connection of macroscopic approach with the description of properties of fluid motion and microscopic kinetic theory. It also presents recent investigations in instabilities and turbulence theory.
This book is about our ordinary concept of matter in the form of enduring continuants and the processes in which they are involved in the macroscopic realm. It emphasises what science rather than philosophical intuition tells us about the world, and chemistry rather than the physics that is more usually encountered in philosophical discussions. The central chapters dealing with the nature of matter pursue key steps in the historical development of scientific conceptions of chemical substance. Like many contemporary discussions of material objects, it relies heavily on mereology. The classical principles are applied to the mereological structure of regions of space, intervals of time, processes and quantities of matter. Quantities of matter, which don’t gain or lose parts over time, are distinguished from individuals, which are typically constituted of different quantities of matter at different times. The proper treatment of the temporal aspect of the features of material objects is a central issue in this book, which is addressed by investigating the conditions governing the application of predicates relating time and other entities. Of particular interest here are relations between quantities of matter and times expressing substance kind, phase and mixture. Modal aspects of these features are taken up in the final chapter.
This book assembles both theory and application in this field, to interest experimentalists and theoreticians alike. Part 1 is concerned with the theory and computing of non-linear optical (NLO) properties while Part 2 reviews the latest developments in experimentation. This book will be invaluable to researchers and students in academia and industry, particularlrly to anyone involved in materials science, theoretical and computational chemistry, chemical physics, and molecular physics.
In this book about metaphysics the author defends a realistic view of universals, characterizing the notion of universal by considering language and logic, the idea of possibility, hierarchies of universals, and causation. He argues that neither language nor logic is a reliable guide to the nature of reality and that basic universals are the fundamental type of universal and are central to causation. All assertions and predications about the natural world are ultimately founded on these basic universals. A distinction is drawn between unified particulars (which reveal natural principle of unity) and arbitrary particulars (which lack such a principle); unified particulars are the terms of causal relations and thus the real constituents of the world. The world is not made up of events but of unified particulars and basic universals.
This book gives an introduction to the theoretical and computational fluid dynamics of a compressible fluid. It focuses on the basic assumptions and the formulation of the theory of compressible flow as well as on the methods of solving problems.
