(EBOOK PDF)Physics for Scientists and Engineers with Modern Physics 4th Edition by Douglas Giancoli 0131495089 9780131495081 full chapters

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• ISBN 10:0131495089 

• ISBN 13:9780131495081 

• Author:Douglas Giancoli  

&>For the calculus-based General Physics course primarily taken by engineers and science majors (including physics majors).
This long-awaited and extensive revision maintains Giancoli’s reputation for creating carefully crafted, highly accurate and precise physics texts. Physics for Scientists and Engineers combines outstanding pedagogy with a clear and direct narrative and applications that draw the student into the physics. The new edition also features an unrivaled suite of media and on-line resources that enhance the understanding of physics.

This book is written for students. It aims to explain physics in a readable and interesting manner that is accessible and clear, and to teach students by anticipating their needs and difficulties without oversimplifying.

Physics is a description of reality, and thus each topic begins with concrete observations and experiences that students can directly relate to. We then move on to the generalizations and more formal treatment of the topic. Not only does this make the material more interesting and easier to understand, but it is closer to the way physics is actually practiced.

Physics for Scientists and Engineers with Modern Physics 4th Table of contents:

etailed Contents
Introduction Journey into Physics
Part I Newton’s Laws
Overview Why Things Change 
Chapter 1 Concepts of Motion 
 1.1 Motion Diagrams 
 1.2  The Particle Model 
 1.3  Position and Time 
 1.4  Velocity 
 1.5  Linear Acceleration 
 1.6  Motion in One Dimension 
 1.7  Solving Problems in Physics
 1.8  Units and Significant Figures 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 2 Kinematics in One Dimension 
 2.1  Uniform Motion 
 2.2  Instantaneous Velocity 
 2.3  Finding Position from Velocity 
 2.4  Motion with Constant Acceleration 
 2.5 Free Fall 
 2.6  Motion on an Inclined Plane 
 2.7  Instantaneous Acceleration 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 3 Vectors and Coordinate Systems 
 3.1  Vectors 
 3.2  Properties of Vectors 
 3.3  Coordinate Systems and Vector Components 
 3.4  Vector Algebra 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 4 Kinematics in Two Dimensions 
 4.1 Acceleration 
 4.2 Kinematics in Two Dimensions 
 4.3 Projectile Motion 
 4.4 Relative Motion 
 4.5 Uniform Circular Motion 
 4.6 Velocity and Acceleration in Uniform Circular Motion 
 4.7 Nonuniform Circular Motion and Angular Acceleration
 SUMMARY
 QUESTIONS AND PROBLEMS
  
Chapter 5 Force and Motion 
 5.1 Force 
 5.2 A Short Catalog of Forces 
 5.3 Identifying Forces 
 5.4 What Do Forces Do? A Virtual Experiment 
 5.5 Newton’s Second Law 
5.6 Newton’s First Law 
5.7 Free-Body Diagrams
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 6 Dynamics I: Motion Along a Line 
 6.1 Equilibrium 
 6.2 Using Newton’s Second Law 
 6.3 Mass, Weight, and Gravity 
6.4 Friction
6.5 Drag
6.6 More Examples of Newton’s Second Law
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 7 Newton’s Third Law 
 7.1 Interacting Objects
 7.2 Analyzing Interacting Objects 
 7.3 Newton’s Third Law 
 7.4 Ropes and Pulleys 
 7.5 Examples of Interacting-Object Problems
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 8 Dynamics II: Motion in a Plane 
 8.1 Dynamics in Two Dimensions 
 8.2 Velocity and Acceleration in Uniform Circular Motion 
 8.3 Dynamics of Uniform Circular Motion 
 8.4 Circular Orbits 
8.5 Fictitious Forces
8.6 Why Does the Water Stay in the Bucket?
8.7 Nonuniform Circular Motion
 SUMMARY
 QUESTIONS AND PROBLEMS
Part Summary Newton’s Laws 
 
Part II Conservation Laws
Overview Why Some Things Don’t Change 
Chapter 9 Impulse and Momentum 
 9.1 Momentum and Impulse 
 9.2 Solving Impulse and Momentum Problems 
 9.3 Conservation of Momentum 
 9.4 Inelastic Collisions 
 9.5 Explosions 
 9.6 Momentum in Two Dimensions 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 10 Energy 
 10.1 A “Natural Money” Called Energy 
 10.2 Kinetic Energy and Gravitational Potential Energy 
 10.3 A Closer Look at Gravitational Potential Energy 
 10.4 Restoring Forces and Hooke’s Law 
 10.5 Elastic Potential Energy 
 10.6 Elastic Collisions 
 10.7 Energy Diagrams 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 11 Work 
 11.1 The Basic Energy Model 
 11.2 Work and Kinetic Energy 
 11.3 Calculating and Using Work 
 11.4 The Work Done by a Variable Force 
 11.5 Force, Work, and Potential Energy 
 11.6 Finding Force from Potential Energy 
 11.7 Thermal Energy 
 11.8 Conservation of Energy 
 11.9 Power 
 SUMMARY
 QUESTIONS AND PROBLEMS
Part Summary Conservation Laws 
 
Part III Applications of Newtonian Mechanics
Overview Power Over Our Environment 
Chapter 12 Rotation of a Rigid Body 
 12.1 Rotational Motion 
 12.2 Rotation About the Center of Mass 
 12.3 Rotational Energy 
 12.4  Calculating Moment of Inertia 
 12.5 Torque 
12.6 Rotational Dynamics
12.7 Rotation About a Fixed Axis
12.8 Static Equilibrium
12.9 Rolling Motion
12.10 The Vector Description of Rotational Motion
12.11 Angular Momentum of a Rigid Body 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 13 Newton’s Theory of Gravity 
 13.1 A Little History 
 13.2 Isaac Newton 
 13.3 Newton’s Law of Gravity 
 13.4 Little g and Big G 
 13.5 Gravitational Potential Energy 
 13.6 Satellite Orbits and Energies 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 14 Oscillations 
 14.1 Simple Harmonic Motion 
 14.2 Simple Harmonic Motion and Circular Motion 
 14.3 Energy in Simple Harmonic Motion 
 14.4 The Dynamics of Simple Harmonic Motion 
 14.5 Vertical Oscillations 
 14.6 The Pendulum 
 14.7 Damped Oscillations 
 14.8 Driven Oscillations and Resonance 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 15 Fluids and Elasticity 
 15.1 Fluids 
 15.2 Pressure 
 15.3 Measuring and Using Pressure 
 15.4 Buoyancy 
 15.5 Fluid Dynamics 
 15.6 Elasticity 
 SUMMARY
 QUESTIONS AND PROBLEMS
Part Summary Applications of Newtonian Mechanics 
 
Part IV Thermodynamics
Overview It’s All About Energy 
Chapter 16 A Macroscopic Description of Matter 
 16.1 Solids, Liquids, and Gases 
 16.2 Atoms and Moles 
 16.3 Temperature 
 16.4 Phase Changes 
 16.5 Ideal Gases 
 16.6 Ideal-Gas Processes 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 17 Work, Heat, and the First Law of Thermodynamics 
 17.1 It’s All About Energy 
 17.2 Work in Ideal-Gas Processes 
 17.3 Heat 
 17.4 The First Law of Thermodynamics 
 17.5 Thermal Properties of Matter 
 17.6 Calorimetry 
17.7 The Specific Heats of Gases 
17.8 Heat-Transfer Mechanisms
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 18 The Micro/Macro Connection 
 18.1 Molecular Speeds and Collisions 
 18.2 Pressure in a Gas 
 18.3 Temperature 
 18.4 Thermal Energy and Specific Heat 
 18.5 Thermal Interactions and Heat 
 18.6  Irreversible Processes and the Second Law of Thermodynamics 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 19 Heat Engines and Refrigerators 
 19.1 Turning Heat into Work 
 19.2 Heat Engines and Refrigerators 
 19.3 Ideal-Gas Heat Engines 
 19.4 Ideal-Gas Refrigerators 
 19.5 The Limits of Efficiency 
 19.6 The Carnot Cycle 
 SUMMARY
 QUESTIONS AND PROBLEMS
Part Summary Thermodynamics 
 
Part V Waves and Optics
Overview Beyond the Particle Model 
Chapter 20 Traveling Waves 
 20.1 The Wave Model 
 20.2 One-Dimensional Waves 
 20.3 Sinusoidal Waves 
 20.4 Waves in Two and Three Dimensions 
 20.5 Sound and Light 
 20.6 Power, Intensity , and Decibels
 20.7 The Doppler Effect 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 21 Superposition 
 21.1 The Principle of Superposition 
 21.2 Standing Waves 
 21.3 Transverse Standing Waves 
 21.4 Standing Sound Waves and Musical Acoustics 
 21.5 Interference in One Dimension 
 21.6 The Mathematics of Interference 
 21.7 Interference in Two and Three Dimensions 
 21.8 Beats 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 22 Wave Optics 
 22.1 Light and Optics 
 22.2 The Interference of Light 
 22.3 The Diffraction Grating 
 22.4 Single-Slit Diffraction 
 22.5 Circular-Aperture Diffraction 
 22.6 Interferometers 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 23 Ray Optics 
 23.1 The Ray Model of Light 
 23.2 Reflection 
 23.3 Refraction 
 23.4 Image Formation by Refraction 
 23.5 Color and Dispersion 
 23.6 Thin Lenses: Ray Tracing 
 23.7 Thin Lenses: Refraction Theory 
 23.8 Image Formation with Spherical Mirrors
 SUMMARY
 QUESTIONS AND PROBLEMS
Chapter 24 Optical Instruments
24.1 Lenses in Combination
24.2 The Camera 
24.3 Vision
24.4 Optical Systems that Magnify
24.5 The Resolution of Optical Instruments 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 25 Modern Optics and Matter Waves 
 25.1 Spectroscopy: Unlocking the Structure of Atoms 
 25.2 X-Ray Diffraction 
 25.3 Photons 
 25.4 Matter Waves 
 25.5 Energy is Quantized 
 SUMMARY
 QUESTIONS AND PROBLEMS
Part Summary Waves and Optics 
 
Part VI Electricity and Magnetism
Overview Charges, Currents, and Fields 
Chapter 26 Electric Charges and Forces 
 26.1 Developing a Charge Model 
 26.2 Charge 
 26.3 Insulators and Conductors 
 26.4 Coulomb’s Law 
 26.5 The Field Model 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 27 The Electric Field 
 27.1 Electric Field Models 
 27.2 The Electric Field of Multiple Point Charges 
 27.3 The Electric Field of a Continuous Charge Distribution 
 27.4 The Electric Fields of Rings, Disks, Planes, and Spheres 
 27.5 The Parallel-Plate Capacitor 
 27.6 Motion of a Charged Particle in an Electric Field 
 27.7 Motion of a Dipole in an Electric Field
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 28 Gauss’s Law 
 28.1 Symmetry 
 28.2 The Concept of Flux 
 28.3 Calculating Electric Flux 
 28.4 Gauss’s Law 
 28.5 Using Gauss’s Law 
 28.6 Conductors in Electrostatic Equilibrium 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 29 The Electric Potential 
 29.1 Electric Potential Energy 
 29.2 The Potential Energy of Point Charges 
 29.3 The Potential Energy of a Dipole 
 29.4 The Electric Potential 
 29.5 The Electric Potential Inside a Parallel-Plate Capacitor 
 29.6 The Electric Potential of a Point Charge 
 29.7 The Electric Potential of Many Charges 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 30 Potential and Field 
 30.1 Connecting Potential and Field 
30.2 Sources of Electric Potential 
 30.3 Finding the Electric Field from the Potential 
 30.4 A Conductor in Electrostatic Equilibrium 
 30.5 Capacitance and Capacitors 
 30.6 The Energy Stored in a Capacitor 
 30.7 Dielectrics 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 31 Current and Resistance
 31.1 The Electron Current 
 31.2 Creating a Current 
 31.3 Current and Current Density 
 31.4 Conductivity and Resistivity 
 31.5 Resistance and Ohm’s Law
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 32 Fundamentals of Circuits 
 32.1 Circuit Elements and Diagrams 
 32.2 Kirchhoff’s Laws and the Basic Circuit 
 32.3 Energy and Power 
 32.4  Series Resistors 
 32.5 Real Batteries 
 32.6  Parallel Resistors 
 32.7 Resistor Circuits 
 32.8 Getting Grounded 
 32.9 RC Circuits 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 33 The Magnetic Field 
 33.1 Magnetism 
 33.2 The Discovery of the Magnetic Field 
 33.3 The Source of the Magnetic Field: Moving Charges 
 33.4 The Magnetic Field of a Current 
 33.5 Magnetic Dipoles 
 33.6 Ampère’s Law and Solenoids 
 33.7 The Magnetic Force on a Moving Charge 
 33.8 Magnetic Forces on Current-Carrying Wires 
 33.9 Forces and Torques on Current Loops 
 33.10 Magnetic Properties of Matter 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 34 Electromagnetic Induction 
 34.1 Induced Currents 
 34.2 Motional emf 
 34.3 Magnetic Flux 
 34.4 Lenz’s Law 
 34.5 Faraday’s Law 
 34.6 Induced Fields
 34.7 Induced Currents: Three Applications 
 34.8 Inductors 
 34.9 LC Circuits 
 34.10 LR Circuits 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 35 Electromagnetic Fields and Waves 
 35.1 E or B? It Depends on Your Perspective 
 35.2 The Field Laws Thus Far
 35.3 The Displacement Current 
 35.4 Maxwell’s Equations 
 35.5 Electromagnetic Waves 
 35.6 Properties of Electromagnetic Waves 
 35.7 Polarization 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 36 AC Circuits 
 36.1 AC Sources and Phasors 
 36.2 Capacitor Circuits 
 36.3 RC Filter Circuits 
 36.4 Inductor Circuits 
 36.5 The Series RLC Circuit 
 36.6 Power in AC Circuits 
 SUMMARY
 QUESTIONS AND PROBLEMS
Part Summary Electricity and Magnetism 
 
Part VII Relativity and Quantum Physics
Overview Contemporary Physics 
Chapter 37 Relativity 
 37.1 Relativity: What’s It All About? 
 37.2 Galilean Relativity 
 37.3 Einstein’s Principle of Relativity 
 37.4 Events and Measurements 
 37.5 The Relativity of Simultaneity 
 37.6 Time Dilation 
 37.7 Length Contraction 
 37.8 The Lorentz Transformations 
 37.9 Relativistic Momentum 
 37.10 Relativistic Energy 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 38 The End of Classical Physics 
 38.1 Physics in the 1800s 
 38.2 Faraday 
 38.3 Cathode Rays 
 38.4 J. J. Thomson and the Discovery of the Electron 
 38.5 Millikan and the Fundamental Unit of Charge 
 38.6 Rutherford and the Discovery of the Nucleus 
 38.7 Into the Nucleus 
 38.8 The Emission and Absorption of Light 
 38.9 Classical Physics at the Limit 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 39 Quantization 
 39.1 The Photoelectric Effect 
 39.2 Einstein’s Explanation 
 39.3 Photons 
 39.4 Matter Waves and Energy Quantization 
 39.5 Bohr’s Model of Atomic Quantization 
 39.6 The Bohr Hydrogen Atom 
 39.7 The Hydrogen Spectrum 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 40 Wave Functions and Uncertainty 
 40.1 Waves, Particles, and the Double-Slit Experiment 
 40.2 Connecting the Wave and Photon Views 
 40.3 The Wave Function 
 40.4 Normalization 
 40.5 Wave Packets 
 40.6 The Heisenberg Uncertainty Principle 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 41 One-Dimensional Quantum Mechanics 
 41.1 Schrödinger’s Equation: The Law of Psi 
 41.2 Solving the Schrödinger Equation 
 41.3 A Particle in a Rigid Box: Energies and Wave Functions 
 41.4 A Particle in a Rigid Box: Interpreting the Solution 
 41.5 The Correspondence Principle 
 41.6 Finite Potential Wells 
 41.7 Wave-Function Shapes 
 41.8 The Quantum Harmonic Oscillator 
 41.9  More Quantum Models 
 41.10 Quantum-Mechanical Tunneling 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 42 Atomic Physics 
 42.1 The Hydrogen Atom: Angular Momentum and Energy 
 42.2 The Hydrogen Atom: Wave Functions and Probabilities 
 42.3 The Electron’s Spin 
 42.4 Multielectron Atoms 
 42.5 The Periodic Table of the Elements 
 42.6 Excited States and Spectra 
 42.7 Lifetimes of Excited States 
 42.8 Stimulated Emission and Lasers 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Chapter 43 Nuclear Physics 
 43.1 Nuclear Structure 
 43.2 Nuclear Stability 
 43.3 The Strong Force 
 43.4 The Shell Model 
 43.5 Radiation and Radioactivity 
 43.6 Nuclear Decay Mechanisms 
 43.7 Biological Applications of Nuclear Physics 
 SUMMARY
 QUESTIONS AND PROBLEMS
 
Part Summary Relativity and Quantum Physics 
Appendix A Mathematics Review
Appendix B Periodic Table of Elements
Appendix C Atomic and Nuclear Data
Answers to Odd-Numbered Questions 
Credits
Index
Library of Congress Subject Headings for this publication:

Physics — Textbooks.

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