Classical mechanics Books

707 products


  • Creative Media Partners, LLC Stochastic Characterization of Cast Metal Microstructure

    15 in stock

    15 in stock

    £22.75

  • 15 in stock

    £22.75

  • 15 in stock

    £22.75

  • Creative Media Partners, LLC Crack Turning in Integrally Stiffened Aircraft Structures

    15 in stock

    15 in stock

    £24.65

  • 15 in stock

    £22.75

  • Creative Media Partners, LLC Stochastic Characterization of Cast Metal Microstructure

    15 in stock

    15 in stock

    £14.96

  • 15 in stock

    £14.09

  • 15 in stock

    £14.09

  • 15 in stock

    £14.96

  • 15 in stock

    £18.95

  • 15 in stock

    £31.46

  • Lulu.com Hydrocyclones Volume II

    15 in stock

    15 in stock

    £71.25

  • Springer analysisofgeometricallynonlinearstructures

    15 in stock

    Book SynopsisBook Contents.- 1 Overview.- 2 Linear Structural Analysis.- 3 Exact Analysis of Trusses.- 4 Nonlinear Analysis of Plane Frames.- 5 Nonlinear Analysis of Space Frames.- 6 Nonlinear Analysis of Membranes.- 7 Cablenets and Fabric Structures.- 8 Three-Dimensional Beam-Columns.- 9 Nonlinear Analysis of Shells.- References.- Appendix 1 Member Stiffness When Beam-Column Effects are Included.- Appendix 2 Determinants.- Appendix 3 The Rotation Matrix.- Appendix 4 Perturbation Methods Applied to Plane Beams.- Appendix 5 Introduction to Computer Programs.- A5.1 Introduction.- A5.2 Space Trusses.- A5.3 Plane Frames.- A5.4 Listing for TR3D.FOR.- A5.5 Listing for FR2D.FOR.- Appendix 6 Graphics on a PC.- A6.1 Introduction.- A6.2 Plotting in 2-D.- A6.3 Drawing Lines in 2-D.Table of ContentsBook Contents.- 1 Overview.- 2 Linear Structural Analysis.- 3 “Exact” Analysis of Trusses.- 4 Nonlinear Analysis of Plane Frames.- 5 Nonlinear Analysis of Space Frames.- 6 Nonlinear Analysis of Membranes.- 7 Cablenets and Fabric Structures.- 8 Three-Dimensional Beam-Columns.- 9 Nonlinear Analysis of Shells.- References.- Appendix 1 Member Stiffness When Beam-Column Effects are Included.- Appendix 2 Determinants.- Appendix 3 The Rotation Matrix.- Appendix 4 Perturbation Methods Applied to Plane Beams.- Appendix 5 Introduction to Computer Programs.- A5.1 Introduction.- A5.2 Space Trusses.- A5.3 Plane Frames.- A5.4 Listing for TR3D.FOR.- A5.5 Listing for FR2D.FOR.- Appendix 6 Graphics on a PC.- A6.1 Introduction.- A6.2 Plotting in 2-D.- A6.3 Drawing Lines in 2-D.

    15 in stock

    £123.49

  • Springer Turbulence in Fluids 84 Fluid Mechanics and Its Applications

    15 in stock

    Book Synopsisto Turbulence in Fluid Mechanics.- Basic Fluid Dynamics.- Transition to Turbulence.- Shear Flow Turbulence.- Fourier Analysis of Homogeneous Turbulence.- Isotropic Turbulence: Phenomenology and Simulations.- Analytical Theories and Stochastic Models.- Two-Dimensional Turbulence.- Beyond Two-Dimensional Turbulence in GFD.- Statistical Thermodynamics of Turbulence.- Statistical Predictability Theory.- Large-Eddy Simulations.- Towards Real World Turbulence.Trade ReviewFrom the reviews of the fourth edition: "Turbulence in Fluids contains a wealth of information, and its author is a top-tier scientist. … The book is logically ordered and contains a comprehensive list of 738 references. … Lesieur’s monograph is recommended for those who already know quite a bit about turbulence, for the theoretically inclined, and in particular for those interested in homogeneous turbulence and geophysical flows and their numerical simulation." (Mohamed Gad-El-Hak, Siam Review, Vol. 51 (1), 2009)Table of Contentsto Turbulence in Fluid Mechanics.- Basic Fluid Dynamics.- Transition to Turbulence.- Shear Flow Turbulence.- Fourier Analysis of Homogeneous Turbulence.- Isotropic Turbulence: Phenomenology and Simulations.- Analytical Theories and Stochastic Models.- Two-Dimensional Turbulence.- Beyond Two-Dimensional Turbulence in GFD.- Statistical Thermodynamics of Turbulence.- Statistical Predictability Theory.- Large-Eddy Simulations.- Towards “Real World Turbulence”.

    15 in stock

    £66.49

  • University Press of the Pacific Theory of Elasticity

    15 in stock

    15 in stock

    £32.25

  • Springer New York Compendium of Theoretical Physics

    15 in stock

    Book SynopsisThe Compendium of Theoretical Physics contains the canonical curriculum of theoretical physics. From classical mechanics over electrodynamics, quantum mechanics and statistical physics/thermodynamics, all topics are treated axiomatic-deductively and confimed by exercises, solutions and short summaries.Table of ContentsPreface.- List of Applications.- 1.Mechanics: Newtonian Mechanics.- Lagrangian Mechanics.- Hamiltonian Mechanics.- Motion of Rigid Bodies.- Central Forces.- Relativistic Mechanics.- 2. Electrodynamics: Formalism of Electrodynamics.- Solutions of Maxwell’s Equations in the Form of Potentials.- Lorentz Covariant Formulation of Electrodynamics.- Radiation Theory.- Time-Independent Electrodynamics.- Electrodynamics in Matter.- Electromagnetic Waves.- Lagrange Formalism in Electrodynamics.- 3. Quantum Mechanics: Mathematical Foundations of Quantum Mechanics.- Formulation of Quantum Theory.- One-Dimensional Systems.- Quantum Mechanical Angular Momenta.- Schrödinger Equation in Three Dimensions.- Electromagnetic Interactions.- Perturbation Theory and Real Hydrogen Atom.- Atomic Transitions.- N-Particle Systems.- Scattering Theory.- 4. Statistical Physics and Thermodynamics: Foundations of Statistical Physics.- Ensemble Theory I: Microcanonical Ensemble and Entropy.- Ensemble Theory II: Canonical and Grand Canonical Ensemble.- Entropy and Information Theory.- Thermodynamics.- Classical Maxwell-Boltzmann Statistics.- Quantum Statistics.- Appendix A: Mathematical Appendix.- Appendix B: Literature List.- Index

    15 in stock

    £64.99

  • Springer Us Technology of the Guitar

    15 in stock

    Book SynopsisFeaturing chapters on physics, structure, sound and design specifics, Technology of the Guitar also includes coverage of historical content, composition of strings and their effects on sound quality, and important designs.Table of Contents1. Guitar Overview.- 2. Basic Physics.- 3. The Structure of the Guitar.- 4. Electronics.- 5. Sound Quality.- 6. Design Specifics for Acoustic Guitars.- 7. Design Specifics for Electric Guitars.- 8. Hardware.- 9. Iconic Guitars.

    15 in stock

    £127.99

  • 15 in stock

    £17.37

  • WWW.Snowballpublishing.com The Principia: Mathematical Principles of Natural Philosophy

    15 in stock

    15 in stock

    £22.49

  • 15 in stock

    £18.52

  • Echo Point Books & Media 507 Mechanical Movements: Mechanisms and Devices

    15 in stock

    15 in stock

    £14.58

  • Echo Point Books & Media 507 Mechanical Movements: Mechanisms and Devices

    15 in stock

    15 in stock

    £19.51

  • Notion Press Media Pvt Ltd Internal Combustion Engine: Volume II

    15 in stock

    15 in stock

    £43.53

  • Springer London Ltd Introduction to Analytical Dynamics

    15 in stock

    Book SynopsisFirst published in 1987, this text offers concise but clear explanations and derivations to give readers a confident grasp of the chain of argument that leads from Newton’s laws through Lagrange’s equations and Hamilton’s principle, to Hamilton’s equations and canonical transformations. This new edition has been extensively revised and updated to include: A chapter on symplectic geometry and the geometric interpretation of some of the coordinate calculations. A more systematic treatment of the conections with the phase-plane analysis of ODEs; and an improved treatment of Euler angles. A greater emphasis on the links to special relativity and quantum theory showing how ideas from this classical subject link into contemporary areas of mathematics and theoretical physics. A wealth of examples show the subject in action and a range of exercises – with solutions – are provided to help test understanding. Trade ReviewFrom the reviews of the second edition:“It is designed to teach analytical mechanics to second and third year undergraduates in the UK, and probably to third or fourth year undergraduates in the US. … This book offers a very attractive traditional introduction to the subject. … the author is well tuned to the difficulties even strong students encounter. … discusses the relevance of classical mechanics in modern physics, especially to relativity and quantum mechanics. This is a fine textbook. It would be a pleasure to teach or to learn from it.” (William J. Satzer, The Mathematical Association of America, March, 2010)Table of ContentsFrames of Reference.- One Degree of Freedom.- Lagrangian Mechanics.- Noether#x2019;s Theorem.- Rigid Bodies.- Oscillations.- Hamiltonian Mechanics.- Geometry of Classical Mechanics.- Epilogue: Relativity and Quantum Theory.

    15 in stock

    £24.95

  • Springer Nature Switzerland AG Flowing Matter

    15 in stock

    Book SynopsisThis open access book, published in the Soft and Biological Matter series, presents an introduction to selected research topics in the broad field of flowing matter, including the dynamics of fluids with a complex internal structure -from nematic fluids to soft glasses- as well as active matter and turbulent phenomena. Flowing matter is a subject at the crossroads between physics, mathematics, chemistry, engineering, biology and earth sciences, and relies on a multidisciplinary approach to describe the emergence of the macroscopic behaviours in a system from the coordinated dynamics of its microscopic constituents. Depending on the microscopic interactions, an assembly of molecules or of mesoscopic particles can flow like a simple Newtonian fluid, deform elastically like a solid or behave in a complex manner. When the internal constituents are active, as for biological entities, one generally observes complex large-scale collective motions. Phenomenology is further complicated by the invariable tendency of fluids to display chaos at the large scales or when stirred strongly enough. This volume presents several research topics that address these phenomena encompassing the traditional micro-, meso-, and macro-scales descriptions, and contributes to our understanding of the fundamentals of flowing matter. This book is the legacy of the COST Action MP1305 “Flowing Matter”.Table of Contents1 Basic concepts of Stokes flows with particles; C. I. Trombley and M. L. Ekiel-Je˙zewska 2 Numerical approaches to complex fluids; Francesco Picano and Luca Brandt 3 Active fluids within the unified colored noise approximation; Umberto Marini Bettolo Marconi, Claudio Maggi and Alessandro Sarracino 4 Upscaling Flow and Transport Processes; M. Icardi 5 Quadrature-based lattice Boltzmann models for rarefied gas flow; Victor E. Ambrus and Victor Sofonea 6 Some recent developments in particle tracking diagnosis in Turbulence research; Mickael Bourgoin 7 Mesoscopic approach to nematic fluids; Miha Ravnik 8 Correlations and nonequilibrium transitions in flowing colloidal glasses; Peter Schall 9 The Finite Volume Approach to Lattice Boltzmann equation; Kalyan Shrestha and Enrico Calzavarini 10 Diffusion, Attachment and Self-Assembly of Janus Particles at Liquid-Liquid and Air-Liquid Interfaces; Andrei Honciuc

    15 in stock

    £44.99

  • Springer Nature Switzerland AG Tensor Analysis for Engineers and Physicists -

    15 in stock

    Book SynopsisThis book unies the common tensor analytical aspects in engineering and physics. Using tensor analysis enables the reader to understand complex physical phenomena from the basic principles in continuum mechanics including the turbulence, its correlations and modeling to the complex Einstein' tensor equation. The development of General Theory of Relativity and the introduction of spacetime geometry would not have been possible without the use of tensor analysis. This textbook is primarily aimed at students of mechanical, electrical, aerospace, civil and other engineering disciplines as well as of theoretical physics. It also covers the special needs of practicing professionals who perform CFD-simulation on a routine basis and would like to know more about the underlying physics of the commercial codes they use. Furthermore, it is suitable for self-study, provided that the reader has a sufficient knowledge of differential and integral calculus. Particular attention was paid to selecting the application examples. The transformation of Cartesian coordinate system into curvilinear one and the subsequent applications to conservation laws of continuum mechanics and the turbulence physics prepares the reader for fully understanding the Einstein tensor equations, which exhibits one of the most complex tensor equation in theoretical physics.Table of ContentsVectors and Tensors.- Transformation of Tensors.- Differential Operators in Continuum Mechanics.- Tensors and Kinematics.- Differential Balances in Continuum Mechanics.- Tensor Operations in Orthogonal Curvilinear.- Tensor Application, Navier-Stokes Equation.- Curves, Curvature, Surfaces, Geodesics.- Turbulent Flow, Modeling.- Special Theory of Relativity.- Tensors In General Theory of Relativity.

    15 in stock

    £66.49

  • Springer Nature Switzerland AG Lectures in Classical Mechanics: With Solved

    15 in stock

    Book SynopsisThis exceptionally well-organized book uses solved problems and exercises to help readers understand the underlying concepts of classical mechanics; accordingly, many of the exercises included are of a conceptual rather than practical nature. A minimum of necessary background theory is presented, before readers are asked to solve the theoretical exercises. In this way, readers are effectively invited to discover concepts on their own. While more practical exercises are also included, they are always designed to introduce readers to something conceptually new. Special emphasis is placed on important but often-neglected concepts such as symmetries and invariance, especially when introducing vector analysis in Cartesian and curvilinear coordinates. More difficult concepts, including non-inertial reference frames, rigid body motion, variable mass systems, basic tensorial algebra, and calculus, are covered in detail. The equations of motion in non-inertial reference systems are derived in two independent ways, and alternative deductions of the equations of motion for variable mass problems are presented. Lagrangian and Hamiltonian formulations of mechanics are studied for non-relativistic cases, and further concepts such as inertial reference frames and the equivalence principle are introduced and elaborated on.Table of ContentsVector Analysis in Cartesian Coordinates.- Vector Analysis in Curvilinear Coordinates.- Kinematics.- Newton's Laws, Dynamics and Galilean Relativity.- Systems of Particles and Variable Mass.- One-Dimensional Potentials and Two-Dimensional Central Potentials.- Non Relativistic Collisions.- Continuous Mass Distributions. Gravitational Potential and Field.- Non-Inertial Reference Systems.- Rigid Body Dynamics.- Special Theory of Relativity.- Relativistic Collisions and Decays.- Non-Relativistic Lagrangian and Hamiltonian Mechanics.

    15 in stock

    £59.99

  • Springer Nature Switzerland AG Physics with Excel and Python: Using the Same

    15 in stock

    Book SynopsisThis book is intended to serve as a basic introduction to scientific computing by treating problems from various areas of physics - mechanics, optics, acoustics, and statistical reasoning in the context of the evaluation of measurements. After working through these examples, students are able to independently work on physical problems that they encounter during their studies. For every exercise, the author introduces the physical problem together with a data structure that serves as an interface to programming in Excel and Python. When a solution is achieved in one application, it can easily be translated into the other one and presumably any other platform for scientific computing. This is possible because the basic techniques of vector and matrix calculation and array broadcasting are also achieved with spreadsheet techniques, and logical queries and for-loops operate on spreadsheets from simple Visual Basic macros. So, starting to learn scientific calculation with Excel, e.g., at High School, is a targeted road to scientific computing. The primary target groups of this book are students with a major or minor subject in physics, who have interest in computational techniques and at the same time want to deepen their knowledge of physics. Math, physics and computer science teachers and Teacher Education students will also find a companion in this book to help them integrate computer techniques into their lessons. Even professional physicists who want to venture into Scientific Computing may appreciate this book.Table of Contents

    15 in stock

    £49.99

  • Springer Nature Switzerland AG Introduction to Orbital Perturbations

    15 in stock

    Book SynopsisThis textbook provides details of the derivation of Lagrange's planetary equations and of the closely related Gauss's variational equations, thereby covering a sorely needed topic in existing literature. Analytical solutions can help verify the results of numerical work, giving one confidence that his or her analysis is correct. The authors—all experienced experts in astrodynamics and space missions—take on the massive derivation problem step by step in order to help readers identify and understand possible analytical solutions in their own endeavors. The stages are elementary yet rigorous; suggested student research project topics are provided.After deriving the variational equations, the authors apply them to many interesting problems, including the Earth-Moon system, the effect of an oblate planet, the perturbation of Mercury's orbit due to General Relativity, and the perturbation due to atmospheric drag. Along the way, they introduce several useful techniques such as averaging, Poincaré's method of small parameters, and variation of parameters. In the end, this textbook will help students, practicing engineers, and professionals across the fields of astrodynamics, astronomy, dynamics, physics, planetary science, spacecraft missions, and others. “An extensive, detailed, yet still easy-to-follow presentation of the field of orbital perturbations.” - Prof. Hanspeter Schaub, Smead Aerospace Engineering Sciences Department, University of Colorado, Boulder “This book, based on decades of teaching experience, is an invaluable resource for aerospace engineering students and practitioners alike who need an in-depth understanding of the equations they use.” - Dr. Jean Albert Kéchichian, The Aerospace Corporation, Retired “Today we look at perturbations through the lens of the modern computer. But knowing the why and the how is equally important. In this well organized and thorough compendium of equations and derivations, the authors bring some of the relevant gems from the past back into the contemporary literature.” - Dr. David A Vallado, Senior Research Astrodynamicist, COMSPOC “The book presentation is with the thoroughness that one always sees with these authors. Their theoretical development is followed with a set of Earth orbiting and Solar System examples demonstrating the application of Lagrange’s planetary equations for systems with both conservative and nonconservative forces, some of which are not seen in orbital mechanics books.” - Prof. Kyle T. Alfriend, University Distinguished Professor, Texas A&M UniversityTable of Contents1 The n-Body Problem2 General Perturbations 3 Evaluation of Lagrange’s Brackets 4 Lagrange’s Planetary Equations 5 Expansion of the Perturbation Function 6 The Earth-Moon System 7 Potential of an Oblate Spheroid8 Effects of General Relativity9 Perturbations due to Atmospheric Drag 10 Periodic Solutions in Nonlinear OscillationsBibliography Projects

    15 in stock

    £34.99

  • Springer Rubber Based Bionanocomposites

    15 in stock

    Book SynopsisRubber based Bionanocomposites.- Cellulose based rubber nanocomposites.- Cellulose in rubber based blends and micro composites.- Chitin based rubber nanocomposites.- Chitin in rubber based blends and micro composites.- Starch based rubber nanocomposites.- Starch in rubber based blends and micro composites.- Soy Protein based Rubber composites and nanocomposites.- PLA based rubber composites and nanocomposites.- Bacterial Cellulose (BC)/ rubber composites and rubber nanocomposites.- Casein based rubber composites and nanocomposites.- Hemi Cellulose rubber composites and rubber nanocomposites.- PHA based rubber composites and nanocomposites.

    15 in stock

    £113.99

  • Springer Current Developments in Solid Mechanics and Their Applications

    15 in stock

    Book SynopsisSurface Electro Elastic Shear Waves in Piezo Electrical Half-Space with Semi Infinite Electrode.- Finite Amplitude Surface Waves in a Linear Electroacoustic (Piezoelectric) Waveguide.- Uniform Asymptotic Expansion for Gegenbauer Polynomials: New Approach.- Asymmetric Buckling of Circular and Annular Plates under Normal Pressure.- Comparison of Hyperelastic Corneal Models for Assessing Eye Deformations After MyoRing Implantation.- Mechanical Effect of Plastic Flow Instabilities at High Strain Rates.- On Possible Chirality and Black Holes of Acoustic Waves in Functionally Graded Rods.- The Effect of the Boundary Conditions on Free Vibrations of a String Resting on a Winkler Foundation.- On Dispersion Relations Within 1D Nonlocal Elasticity.- Analytically-Based Simulation of Guided Wave Scattering by Rectangular Delamination in an Anisotropic Composite Plate.- Bending Waves in Beams Lying on Generalized Deformable Foundations: Elastic, Viscoelastic and Nonlinear-Elastic Ones.- Effect of Curvature on Natural Frequencies of a Cylindrical Shell Closed with the Cap.- Large Torsional Deformations of a Cylindrical Tube Containing Screw Dislocations Under Internal Pressure.- Operator Algebra in Linear Viscoelasticity: Experimental Aspects.- On Flexural Oscillations of Pre-Stressed Circular Beams of Variable Radius Taking into Account Transverse Effects.- Surface Shear Horizontally Wave Propagation in a Half-Space Periodically Stratified with Interfaces of Imperfect Elastic Contact.- Dynamics of a Vortex in a Regulable Rectangular Channel.- On the Plane Contact Problem of a Punch with a Previously Unknown Contact Area in the Presence of Static Friction.- Magneto Electric Coefficients of Thermo-Magneto-Electro ElasticMultilayer Composites: Effective Properties for Nonperfect Connectivity Between Layers.- Diffraction of a Plane Shear Wave by Semi-Infinite Parallel Cracks in a Piezoelectric Space and Propagation of Surface Waves.- Influence of the Moisture Desorption Process on the Modulus of Elasticity and Strength of Lightweight Cement Concrete and Cement Soil Composite.- An Asymptotic Model for the Nonstationary Waves in the Shells of Revolution Initiated by the Longitudinal, Tangential Type Edge Shock Loading.- Modeling of Convective Flows in a Porous Circular Enclosure.- Effect of Nanosized Surface Roughness in Solids with the Account of Steigmann Ogden Mode.- Eigenvalues of a Lightly Loaded Lubricated Oscillating Contact.- Microstructure and Micro and Nano-Properties of Al-Cr-B-N Coatings.- On Model of Coupled Thermomechanics and Electrodynamics.- Numerical Analysis of Novel Composite Sandwich Panels with 3D Printed Cellular Core Under High Velocity Impact.- Investigation of the Effect of Magnetostriction in a Rectangular Dielectric Plate Under the Longitudinal Magnetic Field.- Investigation of the Effect of Magnetostriction in a Rectangular Dielectric Plate Under the Longitudinal Magnetic Field.- Discrimination of Propagating Weak Discontinuities Surfaces in Semi-Isotropic Micropolar Thermoelastic Media.- Three Dimensional Stream Functions and Monogenic Flow Potentials.- Detachment of the Elastic Half Plane from the Punch Attached to it.- The Problem of Interaction of Longitudinal Shear Waves with thin Defects in the Shape of a Broken Line.- Polarization Crosses of Transverse Plane Waves in Micropolar Elastic Media.- Mechanical Quadratures for Solution of the Problem of Torsion of an Inhomogeneous Ageing Viscoelastic Layer by a Round Rigid Washer.- Eigenstrains and Residual Stresses After Gradient Thermomechanical Treatment of Heavy Steel Plate: Numerical Modelling and Experiment.- Fuzzy-Set Methods of Parametric Uncertainty Accounting in the Investigation of Stability Thin-Walled Structures Models.- Development of the Boundary Equations Method for Wave Problems in 2D Domains with Irregularities of the Boundary Curve.- Increasing the Natural Frequency of Oscillations in Functionally Graded Material Rods.- On the Stress State of a Poroelastic Hollow Finite Cylinder.- The Boundary Value Problem of the Behavior of the Transverse Electromagnetic Wave.- Mechanics of Transformable Large Scale Space Structures with Shape Memory Actuator.

    15 in stock

    £113.99

  • Springer Advances in Continuum Physics

    15 in stock

    Book SynopsisWolfgang Dreyer The Life of a Free-Spirited Scientist.- An Eulerian formulation for dissipative materials using Lie derivatives and GENERIC.- Reference map approach to Eulerian thermomechanics using GENERIC.- Pitfalls in the understanding of thermomechanics of continua.- Compressibility and volume variations due to composition in multicomponent fluids.- Incorporating dissipation in the Lagrange equations: Part I Theory.- Incorporating dissipation in the Lagrange equations: Part II Examples.- On Jump Conditions at Phase Boundaries for Ordered and Disordered Phases.- Balance Laws and Transport Theorems for Flows with Singular Interfaces.- Multi Velocity Sharp Interface Continuum Thermodynamics of Fluid Systems with Adsorption.- Damage Modeling in Batteries by Coupling Lithiation and Mechanics by Means of a Finite Element Method.- On the non constant dielectric susceptibility in continuum models for electrolytes.- Elastic Plastic Creep Deformation and Damage in Sn Ag Cu Solder Alloys.- Constitutive theory and simulation of entropy and enthalpy relaxation in the glass transition regime.- Constitutive equations for non linear isotropic limited compressible elastic solids.- Phase field Cosserat modelling of grain boundary pore interaction.- Phase field modeling and sharp interface limits of multi component gas liquid flows with electrochemical reactions and phase transition effects.- Hyperbolic relaxation of the chemical potential in the viscous Cahn Hilliard equation.- A new approach to thermodynamically consistent models for SMAs.- Which frequency bands are responsible for noise-induced triggering of thermoacoustic instabilities?.- A model for tidal effects on a planet.- Mass transport in Fokker Planck equations with general potentials.- Distortion and Residual Stresses in an Additively Manufactured Disc Stack: Continuum Modeling and FEM Simulation for Polyamide 12.- Approaches to conservative Smoothed Particle Hydrodynamics with entropy.- Martensitic nucleation a phonon thermodynamics approach.- The Maximum Entropy Principle in Nonequilibrium Thermodynamics: A Brief History and the Contributions of Wolfgang Dreyer.- Phonon Hydrodynamics Revisited.- On the visual explanation of the isotherm dilute atmosphere.

    15 in stock

    £113.99

  • De Gruyter Classical Mechanics

    15 in stock

    Book SynopsisThis textbook covers all fundamental concepts of physics and describes how different theories are developed from physical observations and phenomena. After some essential calculus the author presents the complete classical mechanics giving numerous examples and with a clear focus on problem-solving techniques. Due to the high number of exercises at the end of each chapter and their solutions the work is valuable for self-study.

    15 in stock

    £65.55

  • De Gruyter Computational Physics: With Worked Out Examples in FORTRAN® and MATLAB®

    15 in stock

    Book SynopsisThe work shows, by means of examples coming from different corners of physics, how physical and mathematical questions can be answered using a computer. Starting with maps and neural networks, applications from Newton's mechanics described by ordinary differential equations come into the focus, like the computation of planetary orbits or classical molecular dynamics. A large part of the textbook is dedicated to deterministic chaos normally encountered in systems with sufficiently many degrees of freedom. Partial differential equations are studied considering (nonlinear) field theories like quantum mechanics, thermodynamics or fluid mechanics. In the second edition, a new chapter gives a detailed survey on delay or memory systems with a direct application to epidemic and road traffic models. Most of the algorithms are realized in FORTRAN, a language most suitable for effectively solving the discussed problems. On the other hand, the codes given and presented on the book’s homepage can be easily translated into other languages. Moreover, several MATLAB examples are presented, mainly for didactic reasons. The book is addressed to advanced Bachelor or Master students of physics, applied mathematics and mechanical engineering.

    15 in stock

    £61.28

  • De Gruyter Quantities and Units: The International System of Units

    15 in stock

    Book SynopsisPrecision and uniformity are indispensable when working with physical quantities, units and formula symbols. Only through unambiguous and authoritative notation is interdisciplinary cooperation possible. The book gives an overview of all common quantities and units, which are needed in studies and teaching as well as in everyday work. All printed quantities and units are currently valid and standardized in ISO/IEC. The book includes: _brief introduction to the development of the system of units _overview on the system of quantities and units _calculating with quantity values _units (international system of units, SI) _notation of numbers _mathematical symbols _Standardized symbols for quantities (mechanics, space and time, radiation, solid state physics, etc.), elements, nuclides, particles and quantum states. _Appendix: conversion to the U.S. customary system of units.

    15 in stock

    £30.40

  • Springer International Publishing AG Turbulence

    15 in stock

    Book SynopsisThis book covers the major problems of turbulence and turbulent processes, including physical phenomena, their modeling and their simulation.After a general introduction in Chapter 1 illustrating many aspects dealing with turbulent flows, averaged equations and kinetic energy budgets are provided in Chapter 2. The concept of turbulent viscosity as a closure of the Reynolds stress is also introduced. Wall-bounded flows are presented in Chapter 3 and aspects specific to boundary layers and channel or pipe flows are also pointed out. Free shear flows, namely free jets and wakes, are considered in Chapter 4. Chapter 5 deals with vortex dynamics. Homogeneous turbulence, isotropy and dynamics of isotropic turbulence are presented in Chapters 6 and 7. Turbulence is then described both in the physical space and in the wave number space. Time dependent numerical simulations are presented in Chapter 8, where an introduction to large eddy simulation is offered. The last three chapters of the book summarize remarkable digital techniques current and experimental. Many results are presented in a practical way, based on both experiments and numerical simulations.The book is written for a advanced engineering students as well as postgraduate engineers and researchers. For students, it contains the essential results as well as details and demonstrations whose oral transmission is often tedious. At a more advanced level, the text provides numerous references which allow readers to find quickly further study regarding their work and to acquire a deeper knowledge on topics of interest.Table of Contents Introduction to turbulence.- Statistical description of turbulent flows.- Wall-bounded turbulent flows.- Free turbulent flows: jets and wakes.- Vortex dynamics.- Homogeneous and isotropic turbulence.- The dynamics of isotropic turbulence.- Direct and large eddy simulation of turbulent flows.- Turbulence models.- Experimental methods.

    15 in stock

    £94.99

  • Springer International Publishing AG Elementary Mechanics Using Python: A Modern Course Combining Analytical and Numerical Techniques

    15 in stock

    Book SynopsisThis book – specifically developed as a novel textbook on elementary classical mechanics – shows how analytical and numerical methods can be seamlessly integrated to solve physics problems. This approach allows students to solve more advanced and applied problems at an earlier stage and equips them to deal with real-world examples well beyond the typical special cases treated in standard textbooks.Another advantage of this approach is that students are brought closer to the way physics is actually discovered and applied, as they are introduced right from the start to a more exploratory way of understanding phenomena and of developing their physical concepts.While not a requirement, it is advantageous for the reader to have some prior knowledge of scientific programming with a scripting-type language. This edition of the book uses Python, and a chapter devoted to the basics of scientific programming with Python is included. A parallel edition using Matlab instead of Python is also available.Last but not least, each chapter is accompanied by an extensive set of course-tested exercises and solutions.Table of ContentsIntroduction.- Getting started with programming.- Units and measurement.- Motion in one dimension.- Forces in one dimension.- Motion in two and three dimensions.- Forces in two and three dimensions.- Constrained motion.- Forces and constrained motion.- Work.- Energy.- Momentum, impulse, and collisions.- Multiparticle systems.- Rotational motion.- Rotation of rigid bodies.- Dynamics of rigid bodies.- Proofs.- Solutions.- Index.

    15 in stock

    £44.99

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Eighth International Conference on Numerical

    15 in stock

    Book SynopsisTable of ContentsComputational aerodynamics and design.- Numerical computations of explosions in gases.- Two-dimensional separated flows.- Numerical simulation of wall-bounded turbulent shear flows.- Shock capturing, fitting and recovery.- Flow simulation by discrete vortex method.- A grid interfacing zonal algorithm for three-dimensional transonic flows about aircraft configurations.- An accurate and efficient finite element Euler equation algorithm.- Numerical computation of large-scale fire-induced flows.- Simulation of the fluctuating field of a forced Jet.- Modeling of gasdynamic processes in neutron stars with phase transitions.- Adaptation of flux-corrected transport algorithms for Modelina blast waves.- A local-relaxation method for solving convection-diffusion equations.- A numerical treatment of two-dimensional flow in a branching channel.- Finite element least square method for solving full steady Euler equations in a plane nozzle.- Analysis of separated boundary-layer flows.- Numerical modelling of inviscid shocked flows of real gases.- An overrelaxation method for transonic flow calculations by Euler equations.- A Dorodnitsyn finite element boundary layer formulation.- Large eddy simulation of a turbulent wall-bounded shear layer with longitudinal curvature.- Mixed initial and boundary value problems: Upwind schemes and their application.- An Eulerian method for calculation of gas motion in a varying region.- Computation of inviscid transonic internal flow.- Random element method for numerical modeling of diffusional processes.- A high Reynolds number flow with closed streamlines.- Compressible swirling flow into a constant volume cylinder.- Techniques for efficient implementation of pseudo-spectral methods and comparisons with finite difference solutions of the Navier-Stokes equations.- Numerical simulation of the fluid flow in front of the scoop of a gas centrifuge.- Study of incompressible turbulent channel flow by large eddy simulation.- Numerical solution and boundary conditions for boundary layer like flows.- Relaxation solution of the full Euler equations.- Spectral simulations of laminar-turbulent transition in plane Poiseuille flow and comparison with experiments.- Transonic-flow computation using an explicit-implicit method.- Numerical modeling of viscous flows in approximation of full and simplified Navier-Stokes equations.- Numerical solution of transonic shear flows past thin bodies.- Transonic potential flow calculation about complex bodies by a technique of overlapping subdomains.- Calculation method for transonic separated flows over airfoils including spoiler effects.- On the use of several compact methods for the study of unsteady incompressible viscous flow for outer problems (II).- Mesh generation strategies for CFD on complex configurations.- A new numerical method for the simulation of three-dimensional flow in a pipe.- An implicit finite-volume method for solving the Euler equations.- Finite difference computation of pressure and wave-drag of slender bodies of revolution at transonic speeds with zero-lift.- Numerical solution of viscous flow in unbounded fluid.- A natural conservative flux difference splitting for the hyperbolic systems of gasdynamics.- Simulation of cylindrical Couette flow.- Solution-adaptive grid for the calculation of three-dimensional laminar and turbulent boundary layers.- Calculation of pressure statistics in turbulent free shear flows by direct numerical simulation.- An implicit finite difference method for chemical nonequilibrium flow through an axisymmetric supersonic nozzle.- Noniterative grid generation using parabolic difference equations for fuselage-wing flow calculations.- The numerical calculation of rotating fluid flows at low Rossby numbers.- Numerical techniques for multidimensional modeling of shock-generated turbulence.- Adaptive curvilinear grids for large Reynolds number viscous flows.- Simulation of large turbulent vortex structures with the parabolic Navier-Stokes equations.- Unigrid projection method to solve the Euler equations for steady transonic flow.- Numerical solution of viscous flow around arbitrary airfoils in a straight cascade.- Numerical simulation of homogeneous anisotropic turbulence.- A composite velocity procedure for the incompressible Navier-Stokes equations.- On calculation accuracy in gas flow problems with shock type discontinuities.- Shock-fitted Euler solutions to shock-vortex interactions.- Euler solutions as limit of infinite Reynolds number for separation flows and flows with vortices.- Branching of Navier-Stokes equations in a spherical gap.- On the construction of adaptive algorithms for unsteady problems of gas dynamics in arbitrary coordinate systems.- Analytical tests for numerical methods in gas dynamics.- Discrete models of the kinetic Boltzman equation.- Application of a polynomial spline in higher-order accurate viscous-flow computations.- Flux-vector splitting for the Euler equations.- Numerical solution of the problem of supersonic flow past wings of arbitrary form with a detached shock wave.- Solution of three-dimensional time-dependent viscous flows.- A minimal residual method for transonic potential flows.- Application of two-point difference schemes to the conservative Euler equations for one-dimensional flows.- Numerical solution of the Euler equation for a compressible flow problem.- A high-resolution numerical technique for inviscid gas-dynamic problems with weak solutions.- Some new developments of the singularity-separating difference method.

    15 in stock

    £44.99

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Theory of Nonlinear Lattices

    15 in stock

    Book SynopsisSoliton theory, the theory of nonlinear waves in lattices composed of particles interacting by nonlinear forces, is treated rigorously in this book. The presentation is coherent and self-contained, starting with pioneering work and extending to the most recent advances in the field. Special attention is focused on exact methods of solution of nonlinear problems and on the exact mathematical treatment of nonlinear lattice vibrations. This new edition updates the material to take account of important new advances.Table of Contents1. Introduction.- 1.1 The Fermi-Pasta-Ulam Problem.- 1.2 Hénon-Heiles Calculation.- 1.3 Discovery of Solitons.- 1.4 Dual Systems.- 2. The Lattice with Exponential Interaction.- 2.1 Finding of an Integrable Lattice.- 2.2 The Lattice with Exponential Interaction.- 2.3 Periodic Solutions.- 2.4 Solitary Waves.- 2.5 Two-Soliton Solutions.- 2.6 Hard-Sphere Limit.- 2.7 Continuum Approximation and Recurrence Time.- 2.8 Applications and Extensions.- 2.9 Poincaré Mapping.- 2.10 Conserved Quantities.- 3. The Spectrum and Construction of Solutions.- 3.1 Matrix Formalism.- 3.2 Infinite Lattice.- 3.3 Scattering and Bound States.- 3.4 The Gel’fand-Levitan Equation.- 3.5 The Initial Value Problem.- 3.6 Soliton Solutions.- 3.7 The Relationship Between the Conserved Quantities and the Transmission Coefficient.- 3.8 Extensions of the Equations of Motion and the Kac-Moerbeke System.- 3.9 The Bäcklund Transformation.- 3.10 A Finite Lattice.- 3.11 Continuum Approximation.- 4. Periodic Systems.- 4.1 Discrete Hill’s Equation.- 4.2 Auxiliary Spectrum.- 4.3 Relation Between ?j (k) and ?j (0).- 4.4 Related Integrals on the Riemann Surface.- 4.5 Solution to the Inverse Problem.- 4.6 Time Evolution.- 4.7 A Simple Example (A Cnoidal Wave).- 4.8 Periodic System of Three-Particles.- 5. Application of the Hamilton-Jacobi Theory.- 5.1 Canonically Conjugate Variables.- 5.2 Action Variables.- 6. Recent Advances in the Theory of Nonlinear Lattices.- 6.1 The KdV Equation as a Limit of the TL Equation.- 6.2 Interacting Soliton Equations.- 6.3 Integrability.- 6.4 Generalization of the TL Equation.- 6.5 Two-Dimensional TL.- 6.6 Bethe Ansatz.- 6.7 The Thermodynamic Limit.- 6.8 Hierarchy of Nonlinear Equations.- 6.9 Some Numerical Results.- Appendices.- Simplified Answers to Main Problems.- References.- List of Authors Cited in Text.

    15 in stock

    £44.99

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Patterns and Interfaces in Dissipative Dynamics

    15 in stock

    Book SynopsisSpontaneous pattern formation in nonlinear dissipative systems far from equilibrium occurs in a variety of settings in nature and technology, and has applications ranging from nonlinear optics through solid and fluid mechanics, physical chemistry and chemical engineering to biology. This book explores the forefront of current research, describing in-depth the analytical methods that elucidate the complex evolution of nonlinear dissipative systems.Trade ReviewFrom the reviews: "This book presents thorough descriptions of analytical methods divulging the complex evolution of nonlinear dissipative systems, and introduces the reader to the forefront of current research. … This book addresses graduate students and non-specialists from the many related areas of applied mathematics, physical chemistry, chemical engineering and biology, as well as the seasoned scientist in search of a modern source of reference." (Ömer Kavaklioglu, Zentralblatt MATH, Vol. 1098 (24), 2006) "This substantial monograph summarizes a broad selection of results concerning the dynamics of model nonlinear dissipative partial differential equations. … The layout and figures are generally very clear and the material is well-organised. … Overall I recommend this book as a very useful reference and guide to the literature. It will undoubtedly be of use to those working in very different areas of nonlinear science." (Jonathan Dawes, Fluid Mechanics, Vol. 584, 2007) "The book begins with a brief overview of dynamical systems theory, which is helpful for understanding the bulk of the book. … In summary, this book is a clear and comprehensive review of this interesting area of pattern formation, and usefully complements existing texts. It is particularly useful as a reference to the development of the theory of stability of fronts and defects." (Alastair M. Rucklidge, Mathematical Reviews, Issue 2008 f)Table of ContentsDynamics, Stability and Bifurcations.- Fronts and Interfaces.- Systems with Separated Scales.- Amplitude Equations for Patterns.- Amplitude Equations for Waves.

    15 in stock

    £44.99

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Food Physics: Physical Properties - Measurement and Applications

    15 in stock

    Book SynopsisThis is the first textbook in this field of increasing importance for the food and cosmetics industries. It is indispensable for future students of food technology and food chemistry as well as for engineers, technologists and technicians in the food industries. It describes the principles of food physics starting with the very basics – and focuses on the needs of practitioners without omitting important basic principles. It will be indispensable for future students of food technology and food chemistry as well as for engineers, technologists and technicians in the food industries. Food Physics deals with the physical properties of food, food ingredients and their measurement.Table of ContentsWater Activity.- Mass and Density.- Geometric Properties: Size and Shape.- Rheological Properties.- Interfacial Phenomena.- Permeability.- Thermal Properties.- Electrical Properties.- Magnetic Properties.- Electromagnetic Properties.- Optical Properties.- Acoustical Properties.- Radioactivity.- On-Line Sensing.- Appendices.-

    15 in stock

    £94.99

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Wave Propagation in Viscoelastic and Poroelastic

    15 in stock

    Book SynopsisWave propagation is an important topic in engineering sciences, especially, in the field of solid mechanics. A description of wave propagation phenomena is given by Graff [98]: The effect of a sharply applied, localized disturbance in a medium soon transmits or 'spreads' to other parts of the medium. These effects are familiar to everyone, e.g., transmission of sound in air, the spreading of ripples on a pond of water, or the transmission of radio waves. From all wave types in nature, here, attention is focused only on waves in solids. Thus, solely mechanical disturbances in contrast to electro-magnetic or acoustic disturbances are considered. of waves - the compression wave similar to the In solids, there are two types pressure wave in fluids and, additionally, the shear wave. Due to continual reflec­ tions at boundaries and propagation of waves in bounded solids after some time a steady state is reached. Depending on the influence of the inertia terms, this state is governed by a static or dynamic equilibrium in frequency domain. However, if the rate of onset of the load is high compared to the time needed to reach this steady state, wave propagation phenomena have to be considered.Table of Contents1. Introduction.- 2. Convolution quadrature method.- 2.1 Basic theory of the convolution quadrature method.- 2.2 Numerical tests.- 2.2.1 Series expansion of the test functions f1 and f2.- 2.2.2 Computing the integration weights ?n.- 2.2.3 Numerical convolution.- 3. Viscoelastically supported Euler-Bernoulli beam.- 3.1 Integral equation for a beam resting on viscoelastic foundation.- 3.1.1 Fundamental solutions.- 3.1.2 Integral equation.- 3.2 Numerical example.- 3.2.1 Fixed-simply supported beam.- 3.2.2 Fixed-free viscoelastic supported beam.- 4. Time domain boundary element formulation.- 4.1 Integral equation for elastodynamics.- 4.2 Boundary element formulation for elastodynamics.- 4.3 Validation of proposed method: Wave propagation in a rod.- 4.3.1 Influence of the spatial and time discretization.- 4.3.2 Comparison with the “classical” time domain BE formulation.- 5. Viscoelastodynamic boundary element formulation.- 5.1 Viscoelastic constitutive equation.- 5.2 Boundary integral equation.- 5.3 Boundary element formulation.- 5.4 Validation of the method and parameter study.- 5.4.1 Three-dimensional rod.- 5.4.2 Elastic foundation on viscoelastic half space.- 6. Poroelastodynamic boundary element formulation.- 6.1 Biot’s theory of poroelasticity.- 6.1.1 Elastic skeleton.- 6.1.2 Viscoelastic skeleton.- 6.2 Fundamental solutions.- 6.3 Poroelastic Boundary Integral Formulation.- 6.3.1 Boundary integral equation.- 6.3.2 Boundary element formulation.- 6.4 Numerical studies.- 6.4.1 Influence of time step size and mesh size.- 6.4.2 Poroelastic half space.- 7. Wave propagation.- 7.1 Wave propagation in poroelastic one-dimensional column.- 7.1.1 Analytical solution.- 7.1.2 Poroelastic results.- 7.1.3 Poroviscoelastic results.- 7.2 Waves in half space.- 7.2.1 Rayleigh surface wave.- 7.2.2 Slow compressional wave in poroelastic half space.- 8. Conclusions — Applications.- 8.1 Summary.- 8.2 Outlook on further applications.- A. Mathematic preliminaries.- A.1 Distributions or generalized functions.- A.2 Convolution integrals.- A.3 Laplace transform.- A.4 Linear multistep method.- B. BEM details.- B.1 Fundamental solutions.- B.1.1 Visco- and elastodynamic fundamental solutions.- B.1.2 Poroelastodynamic fundamental solutions.- B.2 “Classical” time domain BE formulation.- Notation Index.- References.

    15 in stock

    £85.49

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Spectral Methods in Fluid Dynamics

    15 in stock

    Book SynopsisThis is a book about spectral methods for partial differential equations: when to use them, how to implement them, and what can be learned from their of spectral methods has evolved rigorous theory. The computational side vigorously since the early 1970s, especially in computationally intensive of the more spectacular applications are applications in fluid dynamics. Some of the power of these discussed here, first in general terms as examples of the methods have been methods and later in great detail after the specifics covered. This book pays special attention to those algorithmic details which are essential to successful implementation of spectral methods. The focus is on algorithms for fluid dynamical problems in transition, turbulence, and aero­ dynamics. This book does not address specific applications in meteorology, partly because of the lack of experience of the authors in this field and partly because of the coverage provided by Haltiner and Williams (1980). The success of spectral methods in practical computations has led to an increasing interest in their theoretical aspects, especially since the mid-1970s. Although the theory does not yet cover the complete spectrum of applications, the analytical techniques which have been developed in recent years have facilitated the examination of an increasing number of problems of practical interest. In this book we present a unified theory of the mathematical analysis of spectral methods and apply it to many of the algorithms in current use.Table of Contents1. Introduction.- 1.1. Historical Background.- 1.2. Some Examples of Spectral Methods.- 1.2.1. A Fourier Galerkin Method for the Wave Equation.- 1.2.2. A Chebyshev Collocation Method for the Heat Equation.- 1.2.3. A Legendre Tau Method for the Poisson Equation.- 1.2.4. Basic Aspects of Galerkin, Tau and Collocation Methods.- 1.3. The Equations of Fluid Dynamics.- 1.3.1. Compressible Navier-Stokes.- 1.3.2. Compressible Euler.- 1.3.3. Compressible Potential.- 1.3.4. Incompressible Flow.- 1.3.5. Boundary Layer.- 1.4. Spectral Accuracy for a Two-Dimensional Fluid Calculation.- 1.5. Three-Dimensional Applications in Fluids.- 2. Spectral Approximation.- 2.1. The Fourier System.- 2.1.1. The Continuous Fourier Expansion.- 2.1.2. The Discrete Fourier Expansion.- 2.1.3. Differentiation.- 2.1.4. The Gibbs Phenomenon.- 2.2. Orthogonal Polynomials in ( — 1, 1).- 2.2.1. Sturm—Liouville Problems.- 2.2.2. Orthogonal Systems of Polynomials.- 2.2.3. Gauss-Type Quadratures and Discrete Polynomial Transforms.- 2.3. Legendre Polynomials.- 2.3.1. Basic Formulas.- 2.3.2. Differentiation.- 2.4. Chebyshev Polynomials.- 2.4.1. Basic Formulas.- 2.4.2. Differentiation.- 2.5. Generalizations.- 2.5.1. Jacobi Polynomials.- 2.5.2. Mapping.- 2.5.3. Semi-Infinite Intervals.- 2.5.4. Infinite Intervals.- 3. Fundamentals of Spectral Methods for PDEs.- 3.1. Spectral Projection of the Burgers Equation.- 3.1.1. Fourier Galerkin.- 3.1.2. Fourier Collocation.- 3.1.3. Chebyshev Tau.- 3.1.4. Chebyshev Collocation.- 3.2. Convolution Sums.- 3.2.1. Pseudospectral Transform Methods.- 3 2 2 Aliasing Removal by Padding or Truncation.- 3.2.3. Aliasing Removal by Phase Shifts.- 3.2.4. Convolution Sums in Chebyshev Methods.- 3.2.5. Relation Between Collocation and Pseudospectral Methods.- 3.3. Boundary Conditions.- 3.4. Coordinate Singularities.- 3.4.1. Polar Coordinates.- 3.4.2. Spherical Polar Coordinates.- 3.5. Two-Dimensional Mapping.- 4. Temporal Discretization.- 4.1. Introduction.- 4.2. The Eigenvalues of Basic Spectral Operators.- 4.2.1. The First-Derivative Operator.- 4.2.2. The Second-Derivative Operator.- 4.3. Some Standard Schemes.- 4.3.1. Multistep Schemes.- 4.3.2. Runge—Kutta Methods.- 4.4. Special Purpose Schemes.- 4.4.1. High Resolution Temporal Schemes.- 4.4.2. Special Integration Techniques.- 4.4.3. Lerat Schemes.- 4.5. Conservation Forms.- 4.6. Aliasing.- 5. Solution Techniques for Implicit Spectral Equations.- 5.1. Direct Methods.- 5.1.1. Fourier Approximations.- 5.1.2. Chebyshev Tau Approximations.- 5.1.3. Schur-Decomposition and Matrix-Diagonalization.- 5.2. Fundamentals of Iterative Methods.- 5.2.1. Richardson Iteration.- 5.2.2. Preconditioning.- 5.2.3. Non-Periodic Problems.- 5.2.4. Finite-Element Preconditioning.- 5.3. Conventional Iterative Methods.- 5.3.1. Descent Methods for Symmetric, Positive-Definite Systems.- 5.3.2. Descent Methods for Non-Symmetric Problems.- 5.3.3. Chebyshev Acceleration.- 5.4. Multidimensional Preconditioning.- 5.4.1. Finite-Difference Solvers.- 5.4.2. Modified Finite-Difference Preconditioners.- 5.5. Spectral Multigrid Methods.- 5.5.1. Model Problem Discussion.- 5.5.2. Two-Dimensional Problems.- 5.5.3. Interpolation Operators.- 5.5.4. Coarse-Grid Operators.- 5.5.5. Relaxation Schemes.- 5.6. A Semi-Implicit Method for the Navier—Stokes Equations.- 6. Simple Incompressible Flows.- 6.1. Burgers Equation.- 6.2. Shear Flow Past a Circle.- 6.3. Boundary-Layer Flows.- 6.4. Linear Stability.- 7. Some Algorithms for Unsteady Navier—Stokes Equations.- 7.1. Introduction.- 7.2. Homogeneous Flows.- 7.2.1. A Spectral Galerkin Solution Technique.- 7.2.2. Treatment of the Nonlinear Terms.- 7.2.3. Refinements.- 7.2.4. Pseudospectral and Collocation Methods.- 7.3. Inhomogeneous Flows.- 7.3.1. Coupled Methods.- 7.3.2. Splitting Methods.- 7.3.3. Galerkin Methods.- 7.3.4. Other Confined Flows.- 7.3.5. Unbounded Flows.- 7.3.6. Aliasing in Transition Calculations.- 7.4. Flows with Multiple Inhomogeneous Directions.- 7.4.1. Choice of Mesh.- 7.4.2. Coupled Methods.- 7.4.3. Splitting Methods.- 7.4.4. Other Methods.- 7.5. Mixed Spectral/Finite-Difference Methods.- 8. Compressible Flow.- 8.1. Introduction.- 8.2. Boundary Conditions for Hyperbolic Problems.- 8.3. Basic Results for Scalar Nonsmooth Problems.- 8.4. Homogeneous Turbulence.- 8.5. Shock-Capturing.- 8.5.1. Potential Flow.- 8.5.2. Ringleb Flow.- 8.5.3. Astrophysical Nozzle.- 8.6. Shock-Fitting.- 8.7. Reacting Flows.- 9. Global Approximation Results.- 9.1. Fourier Approximation.- 9.1.1. Inverse Inequalities for Trigonometric Polynomials.- 9.1.2. Estimates for the Truncation and Best Approximation Errors.- 9.1.3. Estimates for the Interpolation Error.- 9.2. Sturm—Liouville Expansions.- 9.2.1. Regular Sturm—Liouville Problems.- 9.2.2. Singular Sturm—Liouville Problems.- 9.3. Discrete Norms.- 9.4. Legendre Approximations.- 9.4.1. Inverse Inequalities for Algebraic Polynomials.- 9.4.2. Estimates for the Truncation and Best Approximation Errors.- 9.4.3. Estimates for the Interpolation Error.- 9.5. Chebyshev Approximations.- 9.5.1. Inverse Inequalities for Polynomials.- 9.5.2. Estimates for the Truncation and Best Approximation Errors.- 9.5.3. Estimates for the Interpolation Error.- 9.5.4. Proofs of Some Approximation Results.- 9.6. Other Polynomial Approximations.- 9.6.1. Jacobi Polynomials.- 9.6.2. Laguerre and Hermite Polynomials.- 9.7. Approximation Results in Several Dimensions.- 9.7.1. Fourier Approximations.- 9.7.2. Legendre Approximations.- 9.7.3. Chebyshev Approximations.- 9.7.4. Blended Fourier and Chebyshev Approximations.- 10. Theory of Stability and Convergence for Spectral Methods.- 10.1. The Three Examples Revisited.- 10.1.1. A Fourier Galerkin Method for the Wave Equation.- 10.1.2. A Chebyshev Collocation Method for the Heat Equation.- 10.1.3. A Legendre Tau Method for the Poisson Equation.- 10.2. Towards a General Theory.- 10.3. General Formulation of Spectral Approximations to Linear Steady Problems.- 10.4. Galerkin, Collocation and Tau Methods.- 10.4.1. Galerkin Methods.- 10.4.2. Tau Methods.- 10.4.3. Collocation Methods.- 10.5. General Formulation of Spectral Approximations to Linear Evolution Equations.- 10.5.1. Conditions for Stability and Convergence: The Parabolic Case.- 10.5.2. Conditions for Stability and Convergence: The Hyperbolic Case.- 10.6. The Error Equation.- 11. Steady, Smooth Problems.- 11.1. The Poisson Equation.- 11.1.1. Legendre Methods.- 11.1.2. Chebyshev Methods.- 11.1.3. Other Boundary Value Problems.- 11.2. Advection-Diffusion Equation.- 11.2.1. Linear Advection-Diffusion Equation.- 11.2.2. Steady Burgers Equation.- 11.3. Navier—Stokes Equations.- 11.3.1. Compatibility Conditions Between Velocity and Pressure.- 11.3.2. Direct Discretization of the Continuity Equation: The “inf-sup” Condition.- 11.3.3. Discretizations of the Continuity Equation by an Influence-Matrix Technique: The Kleiser—Schumann Method.- 11.3.4. Navier—Stokes Equations in Streamfunction Formulation.- 11.4. The Eigenvalues of Some Spectral Operators.- 11.4.1. The Discrete Eigenvalues for Lu = ? uxx.- 11.4.2. The Discrete Eigenvalues for Lu = ? vuxx + bux.- 11.4.3. The Discrete Eigenvalues for Lu = ux.- 12. Transient, Smooth Problems.- 12.1. Linear Hyperbolic Equations.- 12.1.1. Periodic Boundary Conditions.- 12.1.2. Non-Periodic Boundary Conditions.- 12.1.3. Hyperbolic Systems.- 12.1.4. Spectral Accuracy for Non-Smooth Solutions.- 12.2. Heat Equation.- 12.2.1. Semi-Discrete Approximation.- 12.2.2. Fully Discrete Approximation.- 12.3. Advection-Diffusion Equation.- 12.3.1. Semi-Discrete Approximation.- 12.3.2. Fully Discrete Approximation.- 13. Domain Decomposition Methods.- 13.1. Introduction.- 13.2. Patching Methods.- 13.2.1. Notation.- 13.2.2. Discretization.- 13.2.3. Solution Techniques.- 13.2.4. Examples.- 13.3. Variational Methods.- 13.3.1. Formulation.- 13.3.2. The Spectral-Element Method.- 13.4. The Alternating Schwarz Method.- 13.5. Mathematical Aspects of Domain Decomposition Methods.- 13.5.1. Patching Methods.- 13.5.2. Equivalence Between Patching and Variational Methods.- 13.6. Some Stability and Convergence Results.- 13.6.1. Patching Methods.- 13.6.2. Variational Methods.- Appendices.- A. Basic Mathematical Concepts.- B. Fast Fourier Transforms.- C. Jacobi—Gauss—Lobatto Roots.- References.

    15 in stock

    £71.24

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Nonlinear Continuum Mechanics of Solids: Fundamental Mathematical and Physical Concepts

    15 in stock

    Book SynopsisThe aim of the book is the presentation of the fundamental mathematical and physical concepts of continuum mechanics of solids in a unified description so as to bring young researchers rapidly close to their research area. Accordingly, emphasis is given to concepts of permanent interest, and details of minor importance are omitted. The formulation is achieved systematically in absolute tensor notation, which is almost exclusively used in modern literature. This mathematical tool is presented such that study of the book is possible without permanent reference to other works.Table of Contents1 Mathematical fundamentals.- 2 Deformation.- 3 Stresses.- 4 Time derivative.- 5 Balance laws.- 6 Constitutive modelling.- Appendix 1.- A1.1 Index notation.- A1.2 Metric tensor and geometrical properties.- A1.3 Vector decompositions, tensor components of first order.- A1.4 Definition of higher-order tensor components.- A1.5 Permutation tensor.- A1.6 Christoffel symbols, covariant differentiation.- References.

    15 in stock

    £85.49

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Elements of Newtonian Mechanics: Including

    15 in stock

    Book SynopsisIn the third edition a number of minor misprints that appeared in the second edition have have been corrected. Furthermore, 17 new problems have been added, at the end of chapters 6, 8, 9, 11, 12, 13, and 14. The answers to these 17 problems have not been listed in the 'Answers' section at the end of the book. This will permit the problems to be used as hand-in problems or perhaps in mid-term exams. JMK €9 PGH Copenhagen May 2000 Preface to the Second Edition In the second edition, a number of misprints that appeared in the first edition have been corrected. In addition to this, we have made improvements based on the experience gathered in the use of the first English edition of the book in the introductory course in physics at the University of Copenhagen. A chapter introducing nonlinear dynamics has been added. The purpose of this chapter is to provide supplementary reading for the students who are interested in this area of active research, where Newtonian mechanics plays an essential role. The students who wish to dig deeper, should consult texts dedicated to the study of nonlinear dynamical systems and chaos. The literature list at the end of this book contains several references for the topic.Trade ReviewThis book provides an excellent introduction to Newtonian mechanics at an undergraduate level, it is used at University of Copenhague. All the classical topics are presented in a very clear way an discussed with many physicaI examples. The book is divided in 16 chapters and contains more than 100 problerns, of various difficulties, with solutions. It's pedagogical conception is absolutely remarkable, all concepts are carefully introduced and physically discussed with mamy details. Foundation of classical mechanics is first introduced and commented on many problems like acceleration of gravity, circular motion or conmunication satellite. Next chapter is devoted to Newton's laws of motion, more than 30 pages of the book contains examples, on direct applications of these law, from: various fields of physics. Gravitational and inertial mass are discussed in the next chapter and is followed by the concept of Galilei transformation. The next three chapters examine the problem of motion respectively of the Earth, in accelerated reference frames and at the kinematic and dynamic point of view. Energy, Center-of Mass and angular momentum theorem are analysed with some details in chapters 8-10. The problem of rigid body including the motion of the planets and the Kepler Iaws are presented and discussed with great attention. The book ends with the important problem of harmonic oscillators and some remarks on non-linear dynamics. In conclusion I warmly recommend this book to everyone interesting in Newtonian mechanics.S. Metens. Physicalia, 2001/XXXVII/4 "The book presents an excellant description of basic principles of classical mechanics....This book can be useful not only to students, but also to specialists who teach the powerful methods of Newtonian mechanics and the imaginary Newton's world governed by laws of classical mechanics."-Zentralblatt MATHTable of Contents1. The Foundation of Classical Mechanics.- 1.1 Principia.- 1.2 Prerequisites for Newton.- 1.3 The Masterpiece.- The Acceleration of Gravity.- Circular Motion.- Communication Satellite.- Horizontal Throw.- The Gravitational Constant.- String Force.- Forces and Tension.- Dimensional Analysis.- 1.4 Concluding Remarks.- 1.5 Problems.- 2. Newton’s Five Laws.- 2.1 Newton’s Laws of Motion.- 2.2 Integration of the Equation of Motion.- Constant Force.- The Harmonic Oscillator.- Mass on a Spring in the Gravitational Field of Earth.- Sphere Falling Through a Liquid.- Solid Against Solid.- The Atwood Machine.- Force in Harmonic Motion.- Charged Particle in a Uniform Magnetic Field.- Thomson’s Experiment.- Work and Energy in Linear Motion of a Particle.- Free Fall Towards the Sun from a Great Distance.- Momentum Conservation.- Inelastic Collisions.- Rocket Propulsion.- Some Qualitative Remarks on Rocket Propulsion.- Ball Against a Wall.- 2.3 Problems.- 3. Gravitational and Inertial Mass.- 3.1 Gravitational Mass.- 3.2 Inertial Mass.- 3.3 Proportionality Between Inertial and Gravitational Mass.- 3.4 Newtonl’s Experiment.- The Satellite.- An Elevator in Free Fall.- Three Balls.- 3.5 Problem.- 4. The Galilei Transformation.- 4.1 The Galilei Transformation.- 4.2 Galileo Speaks.- Velocity Transformation.- 4.3 Problems.- 5. The Motion of the Earth.- 5.1 Examples.- Vectors and the Rotation of a Rigid Body.- Angular Velocities in the Solar System.- 5.2 Problems.- 6. Motion in Accelerated Reference Frames.- 6.1 Newton’s 2nd Law Within Accelerated Reference Frames.- 6.2 The Equivalence Principle of Mechanics.- 6.3 The Einstein Box.- Balloon in Accelerated Frame.- Mass on an Oscillating Plate.- Pendulum in an Elevator.- 6.4 The Centrifugal Force.- Earth’s Orbit Around the Sun.- Grass on a Rotating Disk.- The Variation of g with Latitude.- 6.5 Tidal Fields.- The Roche Limit.- 6.6 The Coriolis Force.- Coriolis Force on a Train.- Particle on a Frictionless Disc.- The Vertical Throw.- 6.7 Tidal Forces and Local Inertial Frames.- Global and Local Inertial Frames.- 6.8 The Foucault Pendulum.- 6.9 Newton’s Bucket.- 6.10 Review: Fictitious Forces.- 6.11 Problems.- 7. The Problem of Motion.- 7.1 Kinematic and Dynamic Views of the Problem of Motion.- 7.2 Einstein Speaks.- 7.3 Symmetry.- 7.4 The Symmetry (Invariance) of Newton’s 2nd Law.- 7.5 Limited Absolute Space.- 7.6 The Asymmetry (Variance) of Newton’s 2nd Law.- 7.7 Critique of the Newtonian View.- 7.8 Concluding Remarks.- 8. Energy.- 8.1 Work and Kinetic Energy.- 8.2 Conservative Force Fields.- 8.3 Central Force Fields.- 8.4 Potential Energy and Conservation of Energy.- 8.5 Calculation of Potential Energy.- Constant Gravitational Field.- Spring Force.- Gravity Outside a Homogeneous Sphere.- 8.6 The Gravitational Field Around a Homogeneous Sphere.- 8.6.1 The Field Around a Spherical Shell.- 8.6.2 A Solid Sphere.- 8.7 Examples.- Particle on a Frictionless Curve.- String Force in the Pendulum.- The Gravitational Potential Outside the Earth.- Potential Energy Due to Electric Forces.- A Tunnel Through the Earth.- The Asymmetry of Nature.- 8.8 Review: Conservative Forces and Potential Energy.- 8.9 Problems.- 9. The Center-of-Mass Theorem.- 9.1 The Center of Mass.- 9.2 The Center-of-Mass Frame.- 9.3 Examples.- Two Masses Connected with a Spring.- Inelastic Collisions.- The Collision Approximation.- Freely Falling Spring.- The Wedge.- 9.4 Review: Center of Mass and Center-of-Mass Theorems.- 9.5 Comments on the Conservation Theorems.- 9.6 Problems.- 10. The Angular Momentum Theorem.- 10.1 The Angular Momentum Theorem for a Particle.- 10.2 Conservation of Angular Momentum.- 10.3 Torque and Angular Momentum Around an Axis.- 10.4 The Angular Momentum Theorem for a System of Particles.- 10.5 Center of Gravity.- 10.6 Angular Momentum Around the Center of Mass.- 10.7 Review: Equations of Motion for a System of Particles.- 10.8 Examples of Conservation of Angular Momentum.- Particle in Circular Motion.- Rotation of Galaxies, Solar Systems, etc.- 11. Rotation of a Rigid Body.- 11.1 Equations of Motion.- 11.2 The Rotation Vector.- 11.3 Kinetic Energy of a Rotating Disk.- 11.3.1 The Parallel Axis Theorem.- 11.3.2 The Perpendicular Axis Theorem.- 11.4 Angular Momentum of an Arbitrary Rigid Body in Rotation Around a Fixed Axis.- 11.4.1 The Parallel Axis Theorem in General Form.- 11.5 Calculation of the Moment of Inertia for Simple Bodies.- 11.5.1 Homogenous Thin Rod.- 11.5.2 Circular Disk.- 11.5.3 Thin Spherical Shell.- 11.5.4 Homogenous (Solid) Sphere, Mass M and Radius R 248.- 11.5.5 Rectangular Plate 249.- 11.6 Equation of Motion for a Rigid Body Rotating Around a Fixed Axis.- 11.6.1 Conservation of Angular Momentum.- 11.7 Work and Power in the Rotation of a Rigid Body Around a Fixed Axis.- 11.7.1 Torsion Pendulum.- 11.8 The Angular Momentum Theorem Referred to Various Points.- 11.9 Examples.- Rotating Cylinder.- Falling Cylinder.- The Atwood Machine.- The Physical Pendulum.- The Rod.- 11.10 Review: Linear Motion and Rotation About a Fixed Axis. 266 11.11 Problems.- 12. The Laws of Motion.- 12.1 Review: Classical Mechanics.- 12.2 Remarks on the Three Conservation Theorems.- 12.3 Examples.- Conservation of Angular Momentum.- Rotating Rod.- Man on Disk.- The Sprinkler.- Rolling.- Yo- Yo on the Floor.- Rolling Over an Edge.- Determinism and Predictability.- 12.4 Problems.- 13. The General Motion of a Rigid Body.- 13.1 Inertia in Rotational Motion.- The Dumbbell.- Flywheel on an Axis.- Precession of a Gyroscope.- 13.2 The Inertia Tensor.- The Dumbbell Revisited.- 13.3 Euler’s Equations.- 13.3.1 Derivation of Euler’s Equations.- 13.4 Kinetic Energy.- 13.5 Determination of the Principal Coordinate System.- Rotating Dumbbell.- Flywheel.- The Gyroscope.- Gyroscope Supported at the Center of Mass.- The Earth as a Gyroscope.- 13.6 Problems.- 14. The Motion of the Planets.- 14.1 Tycho Brahe.- 14.2 Kepler and the Orbit of Mars.- 14.2.1 The Length of a Martian Year.- 14.2.2 The Orbit of the Planet Mars.- 14.2.3 Determination of Absolute Distance in the Solar System.- 14.3 Conic Sections.- 14.4 Newton’s Law of Gravity Derived from Kepler’s Laws.- 14.5 The Kepler Problem.- 14.5.1 Derivation of Kepler’s 3rd Law from Newton’s Law of Gravity.- 14.6 The Effective Potential.- 14.7 The Two-Body Problem.- 14.7.1 The Two-Body Problem and Kepler2019;s 3rd Law.- 14.8 Double Stars: The Motion of the Heliocentric Reference Frame.- 14.9 Review: Kepler Motion.- 14.10 Examples.- Planetary Orbits and Initial Conditions.- Shape and Size of Planetary Orbits.- Motion Near the Surface of the Earth.- Velocities in an Elliptical Orbit.- Hohman Orbit to Mars.- The Face of the Moon (Spin-Orbit Locking).- 14.11 Problems.- 15. Harmonic Oscillators.- 15.1 Small Oscillations.- 15.2 Energy in Harmonic Oscillators.- 15.3 Free Damped Oscillations.- 15.3.1 Weakly Damped Oscillations.- 15.3.2 Strongly Damped Oscillations.- 15.3.3 Critical Damping.- 15.4 Energy in Free, Weakly Damped Oscillations.- 15.5 Forced Oscillations.- 15.6 The Forced Damped Harmonic Oscillator.- 15.7 Frequency Characteristics.- 15.7.1 ? ? ?0: A Low Driving Frequency.- 15.7.2 ? ? ?0: A High Driving Frequency.- 15.7.3 ? ? ?0: Resonance.- 15.8 Power Absorption.- 15.9 The Q-Value of a Weakly Damped Harmonic Oscillator.- 15.10 The Lorentz Curve.- 15.11 Complex Numbers.- 15.12 Problems.- 16. Remarks on Nonlinearity and Chaos.- 16.1 Determinism vs Predictability.- 16.2 Linear and Nonliner Differential Equations.- Superposition.- 16.3 Phase Space.- The Simple Harmonic Oscillator.- Phase Space of the Pendulum.- Bifurcation in a Nonlinear Model.- 16.4 A Forced, Damped Nonlinear Oscillator.- 16.5 Liapunov Exponents.- 16.6 Chaos in the Solar System.- 16.7 Problems.- Appendix. Vectors and Vector Calculus.- Selected References.- Answers to Problems.

    15 in stock

    £54.99

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Convective and Advective Heat Transfer in Geological Systems

    15 in stock

    Book SynopsisThe study of heat transfer mechanisms in hydrothermal systems is important for understanding the basic physics behind orebody formation and mineralization in the upper crust (Bickle and Mckenzie 1987; Bjorlykke et al. 1988; Brady 1988; England and Thompson 1989; Hoisch 1991; Connolly 1997). Generally, heat energy may be transferred within the crust in the following forms: conduction, advection (including forced convection) where the heat is carried by a moving mass of rock during def- mation or by a moving uid, convection (i. e. , free convection, natural convection, buoyancy driven convection, temperature gradient driven convection) and a com- nation of these processes. Since advective ow is usually generated by a pore- uid pressure gradient, heat transfer due to advective ow is largely dependent on the pore- uid pressure gradient distribution in hydrothermal systems. A typical ex- ple of this advective ow is the upward through ow caused by lithostatic pore- uid pressure gradients within the lower crust. Extensive studies (Connolly and Ko 1995; Etheridge et al. 1983; England et al. 1987; Fyfe et al. 1978; Walther and Orville 1982; Peacock 1989; Yardley and Bottrell 1992; Hanson 1992; Yardley and Lloyd 1995; Norton and Knapp 1970) have shown that lithostatic pore- uid pressure can be built up by metamorphic uids arising from devolatilization and dehydration - actions, if the permeability is low enough to control uid ow in the lower crust.Table of ContentsDistribution of Pore-Fluid Pressure Gradient in the Crust with Temperature Neglected.- Pore-Fluid Pressure Gradients in the Crust with Heat Conduction and Advection.- Convective Heat Transfer in a Homogeneous Crust.- Convective Heat Transfer in a Heterogeneous Crust.- Pore-Fluid Focusing within Two-Dimensional Faults and Cracks of Crustal Scales with No Temperature Effects: Solutions Expressed in a Local Coordinate System.- Pore-Fluid Focusing within Two-Dimensional Faults and Cracks of Crustal Scales with No Temperature Effects: Solutions Expressed in a Global Coordinate System.- Pore-Fluid Flow Focused Transient Heat Transfer within and around Two-Dimensional Faults and Cracks of Crustal Scales.- Convective Heat Transfer within Three-Dimensional Vertical Faults Heated from Below.- Convective Heat Transfer within Three-Dimensional Inclined Faults Heated from Below.- Double-Diffusion Driven Convective Heat Transfer within Three-Dimensional Vertical Faults Heated from Below.- Convection Induced Ore Body Formation and Mineralization within the Upper Crust of the Earth.

    15 in stock

    £85.49

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Basic Theoretical Physics: A Concise Overview

    15 in stock

    Book SynopsisThis concise treatment embraces, in four parts, all the main aspects of theoretical physics. Recent topics such as holography and quantum cryptography are included. The book summarizes what a graduate student, physicist working in industry, or a physics teacher should master during his or her degree course. It will also be useful for deepening one’s insight and it adds new dimensions to understanding of these elemental concepts.Trade ReviewFrom the reviews: "A comprehensive work covering the material that graduate students in physics typically would study in preparing for doctoral candidacy examinations. … This book would be very useful for self-study by motivated students, or for preparation for candidacy exams. … Practicing physicists may find that the brief, accessible treatments of many topics will earn this book a place on a convenient bookshelf. Summing Up: Recommended. Upper-division undergraduates through professionals." (M. C. Ogilvie, CHOICE, Vol. 45 (7), 2008) "The book, written by two … ‘working physicists’, contains what the authors regard as being ‘basic knowledge’ in the standard courses of theoretical physics (yet) held at German Universities. … is primarily intended to cover the ‘Basic Theoretical Physics’ in a single and handy volume. … Hence, the book should be considered as being a kind of ‘compendium’ of … formulas used in theoretical physics where the formulas are filled in between with some remarks." (Jürgen Tolksdorf, Zentralblatt MATH, Vol. 1134 (12), 2008)Table of ContentsFrom the contents: Part I: Mechanics and Aspects of Relativity.- Space and Time.- Force and Mass.- Basic tasks of Mechanics for one-dimensional motions.-The damped and driven harmonic oscillator.- The three fundamental conservation laws.- Motion in central force fields.- The Rutherford scattering cross section.- Lagrange formalism I : The Lagrangian and the Hamiltonian.- Relativity I: Einstein's principle of the shortest proper time and Hamilton's principle of least-action momentum.- Coupled small oscillations.- Rigid bodies.- Remarks on non-integrable systems.- Lagrange formalism II: Constraints.- Accelerated reference frames.- Relativity II: E=mc².- Part II: Electrodynamics and aspects of optics.- Opening: Literature, internet, contents, purpose.- Introduction: units and (mathematical) prelimaries.- Electrostatics and magnetostatics.- Magnetic field of steady electric currents.- The general Maxwell equations I: Faraday's 'law of induction.- Maxwell's displacement current.- The general Maxwell equations II: Electromagnetic waves.- Applications of the electrodynamics in the field of optics.- Conclusion.- Part III: Quantum mechanics.- Introductory remarks.- References and internet.- On the history of quantum mechanics.- Quantum mechanics: Foundations.- One-dimensional problems.- The harmonic oscillator in the wave mechanics.- The hydrogen atom in the wave mechanics.- Abstract quantum mechanics (algebraic methods).- Spin momentum and Pauli's principle (the spin-statistics theorem).- Spin-orbit interaction.- The minimisation principle of Ritz.- Schrödinger's perturbation theory for the statics.- Time-dependent perturbations.- Magnetism as an essentially quantum-mechanical phenomenon.- Cooper pairs.- On the interpretation of quantum mechanics.- Conclusion: Repetition and summary on the history of quantum mechanics.- Looking back and looking forward.- Appendix: On cryptography and quantum cryptography.- Part IV: Thermodynamics and Statistical Physics.- Introductionand overview.- Phenomenological thermodynamics: Temperature and heat.- The fundamental theorems I and II.- Phase transitions, van der Waals theory and related problems.- Kinetic gas theory.- Statistical Physics.- From quantum statistics to the classical statistical physics.- Deepening of the fundamental theorem II.- Shannon's information entropy.- The set of canonical ensembles in the phenomenological thermodynamics.- The relation of Clausius and Clapeyron.- Generation of low and ultralow temperatures, and the fundamental theorem III.- General statistical physics (formal completion): The statistical operator and the trace formalism.- Ideal Bose and Fermi gases.- Applications I.- Applications II.- Conclusion

    15 in stock

    £54.99

  • Springer-Verlag Berlin and Heidelberg GmbH & Co. KG Fundamentals of Shock Wave Propagation in Solids

    15 in stock

    Book SynopsisMy intent in writing this book is to present an introduction to the thermo- chanical theory required to conduct research and pursue applications of shock physics in solid materials. Emphasis is on the range of moderate compression that can be produced by high-velocity impact or detonation of chemical exp- sives and in which elastoplastic responses are observed and simple equations of state are applicable. In the interest of simplicity, the presentation is restricted to plane waves producing uniaxial deformation. Although applications often - volve complex multidimensional deformation fields it is necessary to begin with the simpler case. This is also the most important case because it is the usual setting of experimental research. The presentation is also restricted to theories of material response that are simple enough to permit illustrative problems to be solved with minimal recourse to numerical analysis. The discussions are set in the context of established continuum-mechanical principles. I have endeavored to define the quantities encountered with some care and to provide equations in several convenient forms and in a way that lends itself to easy reference. Thermodynamic analysis plays an important role in continuum mechanics, and I have included a presentation of aspects of this subject that are particularly relevant to shock physics. The notation adopted is that conventional in expositions of modern continuum mechanics, insofar as possible, and variables are explained as they are encountered. Those experienced in shock physics may find some of the notation unconventional.Table of ContentsMechanical Principles.- Plane Longitudinal Shocks.- Material Response I: Principles.- Material Response II: Inviscid Compressible Fluids.- Material Response III: Elastic Solids.- Material Response IV: Elastic-Plastic and Elastic-Viscoplastic Solids.- Weak Elastic Waves.- Finite-amplitude Elastic Waves.- Elastic-Plastic and Elastic-Viscoplastic Waves.- Porous Solids.- Spall Fracture.- Steady Detonation Waves.

    15 in stock

    £54.99

© 2026 Book Curl

    • American Express
    • Apple Pay
    • Diners Club
    • Discover
    • Google Pay
    • Maestro
    • Mastercard
    • PayPal
    • Shop Pay
    • Union Pay
    • Visa

    Login

    Forgot your password?

    Don't have an account yet?
    Create account