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The Energy of Physics, Part I: Classical Mechanics and Thermodynamics provides students the opportunity to learn physics the way in which physicists understand the discipline. In contrast to standard textbooks, which introduce forces first, this text begins with classical mechanics using the concept of energy conservation. By inverting the standard order of presentation, the book enables students to understand and use calculus effectively, particularly toward applications in physics. Energy conservation is a constant theme throughout the text. Newton's laws are presented in terms of work and changes in kinetic energy, and forces are introduced as the derivative of potential energy, which is necessary for defining equilibrium conditions. A generalization of forces and Newton's laws then motivates the concepts of linear and angular momentum. The mode of presentation also allows thermodynamics to be incorporated throughout the text. The second edition includes a new chapter on fluids and new and additional practice problems for all chapters. The Energy of Physics, Part I gives students a better understanding of classical mechanics and provides a solid foundation for more advanced physics concepts and courses. The text is ideal for calculus-based physics courses for science and engineering majors.
The Energy of Physics Part II: Electricity and Magnetism steps away from the traditional chronological organization of material and instead groups similar topics together, thus enabling students to better understand potentials and fields and the relationship between electricity and magnetism. In opening chapters, the concepts of potential and field are introduced in the context of the gravitational, electric, and magnetic interactions between point particles.
""The Energy of Physics, Part I: Classical Mechanics and Thermodynamics" gives students the opportunity to learn physics in the way that physicists understand the discipline. In contrast to standard textbooks, which introduce forces first, "The Energy of Physics" begins with classical mechanics using the concept of energy conservation. By inverting the standard order of presentation, the book enables students to understand and to use calculus effectively, particularly towards applications in physics. Energy conservation is also a constant theme throughout "The Energy of Physics." Newton's laws are first presented in terms of work and changes in kinetic energy, and forces are introduced as the derivative of potential energy which is necessary for defining equilibrium conditions. A generalization of forces and Newton's laws then motivates the concepts of linear and angular momentum. The mode of presentation also allows thermodynamics to be incorporated throughout the text. "The Energy of Physics" gives students a better understanding of classical mechanics and provides a solid foundation for more advanced physics concepts and courses. The fresh, unique approach of "The Energy of Physics" makes it an ideal teaching tool for calculus-based physics courses for science and engineering majors. Christopher J. Fischer is an associate professor in the Department of Physics and Astronomy at the University of Kansas, Lawrence. He holds a Ph.D. in applied physics from the University of Michigan, Ann Arbor. His research focuses on biophysics with an emphasis on understanding the function of molecular motors, especially those that manipulate DNA structure. He has been extensively involved in curriculum development at the University of Kansas, including the redesign of the introductory calculus-based physics sequence.
The Energy of Physics Part II: Electricity and Magnetism steps away from the traditional chronological organization of material and instead groups similar topics together, thus enabling students to better understand potentials and fields and the relationship between electricity and magnetism. In opening chapters, the concepts of potential and field are introduced in the context of the gravitational, electric, and magnetic interactions between point particles. Later chapters discuss the electric and magnetic fields and potentials of distributions of electric charge, the multipole expansions of these fields and potentials, and Maxwell's Equations. The final chapters focus on electric circuits, with particular emphasis on AC circuits, electromagnetic waves, and optics. Appendices provide additional support in applied mathematics, derivations of key equations, further discussion of select examples, and more. The second edition features extensive revisions to the majority of the chapters, new problems for all chapters, and updated material in the appendices. The Energy of Physics Part II builds on the energy-based approach to classical mechanics presented in Part I and has the similar goal of helping students develop their applied mathematics skills. The book can be used in any calculus-based introductory electricity and magnetism course, especially those in physical sciences, engineering, and mathematics. Christopher J. Fischer holds a Ph.D. in applied physics from the University of Michigan, Ann Arbor. Dr. Fischer is the associate chair of the Department of Physics and Astronomy and the director of the Engineering Physics Program at the University of Kansas, Lawrence. He has been extensively involved in curriculum development, including the redesign of the university's introductory calculus-based sequence. Dr. Fischer's research focuses on both biophysics and physics education.
The Energy of Physics, Part I: Classical Mechanics and Thermodynamics gives students the opportunity to learn physics in the way that physicists understand the discipline. In contrast to standard textbooks, which introduce forces first, The Energy of Physics begins with classical mechanics using the concept of energy conservation. By inverting the standard order of presentation, the book enables students to understand and to use calculus effectively, particularly towards applications in physics. Energy conservation is also a constant theme throughout The Energy of Physics. Newton's laws are first presented in terms of work and changes in kinetic energy, and forces are introduced as the derivative of potential energy which is necessary for defining equilibrium conditions. A generalization of forces and Newton's laws then motivates the concepts of linear and angular momentum. The mode of presentation also allows thermodynamics to be incorporated throughout the text. The Energy of Physics gives students a better understanding of classical mechanics and provides a solid foundation for more advanced physics concepts and courses. The fresh, unique approach of The Energy of Physics makes it an ideal teaching tool for calculus-based physics courses for science and engineering majors.
A beloved introductory physics textbook, now including exercises and an answer key, explains the concepts essential for thorough scientific understanding In this concise book, R. Shankar, a well-known physicist and contagiously enthusiastic educator, explains the essential concepts of Newtonian mechanics, special relativity, waves, fluids, thermodynamics, and statistical mechanics. Now in an expanded edition—complete with problem sets and answers for course use or self-study—this work provides an ideal introduction for college-level students of physics, chemistry, and engineering; for AP Physics students; and for general readers interested in advances in the sciences. The book begins at the simplest level, develops the basics, and reinforces fundamentals, ensuring a solid foundation in the principles and methods of physics.
This introduction to classical mechanics and thermodynamics provides an accessible and clear treatment of the fundamentals. Starting with particle mechanics and an early introduction to special relativity this textbooks enables the reader to understand the basics in mechanics. The text is written from the experimental physics point of view, giving numerous real life examples and applications of classical mechanics in technology. This highly motivating presentation deepens the knowledge in a very accessible way. The second part of the text gives a concise introduction to rotational motion, an expansion to rigid bodies, fluids and gases. Finally, an extensive chapter on thermodynamics and a short introduction to nonlinear dynamics with some instructive examples intensify the knowledge of more advanced topics. Numerous problems with detailed solutions are perfect for self study.
This book starts from a set of common basic principles to establish the basic formalisms of all disciplines of fundamental physics, including quantum field theory, quantum mechanics, statistical mechanics, thermodynamics, general relativity, electromagnetism, and classical mechanics. Instead of the traditional pedagogic way, the author arranges the subjects and formalisms in a logical order, i.e. all the formulas are derived from the formulas before them. The formalisms are also kept self-contained. Most mathematical tools are given in the appendices. Although this book covers all the disciplines of fundamental physics, it contains only a single volume because the contents are kept concise and treated as an integrated entity, which is consistent with the motto that simplicity is beauty, unification is beauty, and thus physics is beauty.This can be used as an advanced textbook for graduate students. It is also suitable for physicists who wish to have an overview of fundamental physics.
This outstanding volume in the McGraw-Hill International Series in Pure and Applied Physics provides solid coverage of the principles of mechanics in a well-written, accessible style. Topic coverage for the second edition of Classical Mechanics: A Modern Perspective includes linear motion, energy conservation, Lagrange's equations, momentum conservation, as well as discussions of nonlinear mechanics and relativity. The text is comprehensive and designed to be appropriate for one- or two-semester introductory mechanics courses. Drs. Barger and Olsson have taken great care to provide readers with the most understandable presentation possible, including an abundance of new and relevant examples, problems, and interesting applications. In order to develop the most up-to-date coverage of mechanics in the second edition, the authors have included modern coverage of topics in chaos and cosmology, as well as numerous discussions of numerical techniques.
This book studies electricity and magnetism, light, the special theory of relativity, and modern physics.