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An account of Max Planck’s construction of his theory of blackbody radiation, summarizing the established physics on which he drew. In the last year of the nineteenth century, Max Planck constructed a theory of blackbody radiation—the radiation emitted and absorbed by nonreflective bodies in thermal equilibrium with one another—and his work ushered in the quantum revolution in physics. In this book, three physicists trace Planck’s discovery. They follow the trail of Planck’s thinking by constructing a textbook of sorts that summarizes the established physics on which he drew. By offering this account, the authors explore not only how Planck deployed his considerable knowledge of the physics of his era but also how Einstein and others used and interpreted Planck’s work. Planck did not set out to lay the foundation for the quantum revolution but to study a universal phenomenon for which empirical evidence had been accumulating since the late 1850s. The authors explain the nineteenth-century concepts that informed Planck’s discovery, including electromagnetism, thermodynamics, and statistical mechanics. In addition, the book offers the first translations of important papers by Ludwig Boltzmann and Wilhelm Wien on which Planck’s work depended.

An account of the concepts and intellectual structure of classical thermodynamics that reveals the subject's simplicity and coherence.

Seeing Physics uses drawings to help explain 51 key ideas of physics in an accessible and engaging way.

Preface; Acknowledgments; 1. Introduction; 2. Mechanics; 3. Hydrodynamics; 4. Temperature and heat; 5. Electrodynamics and plasma physics; 6. Quantum physics; 7. Dimensional cosmology; 8. Appendix. Answers to problems; Index.

Focusing on the concept of entropy, this book serves as a valuable resource for students in physics, engineering, chemistry, and mathematics. It aims to clarify the complexities surrounding entropy, making it more accessible for undergraduate learners. Through detailed explanations and practical examples, readers will gain a deeper understanding of this fundamental principle and its applications across various scientific disciplines.

The book features end-of-chapter practice problems, an appendix of worked problems, a glossary of terms, and an annotated bibliography.

Students will find this book a useful aid to learning the unfamiliar mathematical aspects of stochastic processes while applying them to physical processes that he or she has already encountered.

Exploring the concept of "perfect form," this book delves into the variational principles of classical physics, illustrating how natural and artificial shapes optimize physical quantities like time and energy. It introduces key concepts such as least action and Hamilton's principle, using the calculus of variations as a mathematical framework. By connecting the path of light, the motion of a baseball, and the curve of a wheat stalk, it offers a comprehensive understanding of how these principles manifest in both everyday phenomena and foundational physics.