UNIVERSITY PHYSICS UNIVERSITY PHYSICS SEARS AND ZEMANSKY’S SEARS AND ZEMANSKY’S WITH MODERN PHYSICS FIRST AUSTRALIAN SI EDITION WITH S MODERN E A W R PHYSICS S I T A H N D M FFIIRRSSTT AAUUSSTTRRAALLIIAANN Z MasteringPhysics provides the most advanced, educationally effective and O E M SSII EEDDIITTIIOONN widely used online physics tutorial and assessment system in the world. D E A MasteringPhysics is designed to provide you with customised coaching N R S and individualised feedback to help improve problem-solving skills. N K Studies show that fi nal exam grades are higher when students complete P Y ’ H S assignments in MasteringPhysics. YU S MasteringPhysics includes: N I C • tutorial-based assignments with hints and feedback as you work I S V through the problem F IE R • ActivPhysics, a highly acclaimed, comprehensive library of applet- SR T YY OO UU NN GG based activities which use dynamic, interactive applets and staged AS U I questions to help you learn by doing and visualising the problem to be STT FREEDMAN R solved. AY L I BBHHAATTHHAALL AP Register for MasteringPhysics at www.pearson.com.au/masteringphysics N SH I EY D ITS I OI NC S YY OO UU NN GG ISBN 978-1-4425-1711-0 FFRREEEEDDMMAANN BBHHAATTHHAALL PEARSON AUSTRALIA is a division of 9 781442 517110 Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page i SEARS AND ZEMANSKY’S UN I V E R S IT Y P H Y S ICS WITH MODERN PHYSICS FIRST AUSTRALIAN SI EDITION Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page ii Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page iii SEARS AND ZEMANSKY’S UN I V E R S IT Y P H Y S ICS WITH MODERN PHYSICS FIRST AUSTRALIAN SI EDITION HHUUGGHH DD.. YYOOUUNNGG CARNEGIE MELLON UNIVERSITY RROOGGEERR AA.. FFRREEEEDDMMAANN UNIVERSITY OF CALIFORNIA, SANTA BARBARA RRAAGGBBIIRR BBHHAATTHHAALL UNIVERSITY OF WESTERN SYDNEY CCOONNTTRRIIBBUUTTIINNGG AAUUTTHHOORR AA.. LLEEWWIISS FFOORRDD TEXAS A&M UNIVERSITY Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page iv Copyright ©Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 Pearson Australia Unit 4, Level 3 14 Aquatic Drive Frenchs Forest NSW 2086 www.pearson.com.au Authorised adaptation from the United States edition entitled University Physics with Modern Physics, 12th edition, ISBN 0321501217 by Young, Hugh D.; Freedman, Roger A.; Ford, Lewis, published by Pearson Education, Inc, publishing as Addison-Wesley, Copyright ©2008. First adaptation edition published by Pearson Australia, Copyright ©2011 The Copyright Act 1968of Australia allows a maximum of one chapter or 10% of this book, whichever is the greater, to be copied by any educational institution for its educational purposes provided that that educational institution (or the body that administers it) has given a remuneration notice to Copyright Agency Limited (CAL) under the Act. Fordetails of the CAL licence for educational institutions contact: Copyright Agency Limited, telephone: (02) 9394 7600, email: [email protected] All rights reserved. Except under the conditions described in the Copyright Act 1968of Australia and subsequent amendments, no part of this publication may be reproduced, stored in a retrieval system or transmitted in any form orby any means, electronic, mechanical, photocopying, recording or otherwise, without the prior permission of the copyright owner. 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Pearson Australia is a division of Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page v BRIEF CONTENTS 24 Detailed Contents vi Capacitance and Dielectrics 791 Preface xiii 25 Current, Resistance About the Authors xix and Electromotive Force 822 Acknowledgements xx 26 Direct-Current Circuits 855 27 Mechanics Magnetic Field and Magnetic Forces 886 28 1 Sources of Magnetic Field 926 Units, Physical Quantities and Vectors 1 29 2 Electromagnetic Induction 961 Motion Along a Straight Line 34 30 3 Inductance 996 Motion in Two or Three Dimensions 69 31 4 Alternating Current 1026 Newton’s Laws of Motion 104 32 5 Electromagnetic Waves 1056 Applying Newton’s Laws 132 6 Work and Kinetic Energy 175 Optics 7 Potential Energy 33 and Energy Conservation 205 The Nature and Propagation of Light 1085 8 Momentum, Impulse and Collisions 238 34 Geometric Optics and Optical Instruments 1120 9 Rotation of Rigid Bodies 275 35 Interference 1169 10 Dynamics of Rotational Motion 305 36 Diffraction 1196 11 Equilibrium and Elasticity 342 12 Gravitation 371 Modern Physics 13 Periodic Motion 407 37 Relativity 1228 14 Fluid Mechanics 444 38 Photons, Electrons and Atoms 1266 39 The Wave Nature of Particles 1307 Waves/Acoustics 40 Quantum Mechanics 1333 15 Mechanical Waves 472 41 Atomic Structure 1358 16 42 Sound and Hearing 511 Molecules and Condensed Matter 1389 43 Nuclear Physics 1424 Thermodynamics 44 Particle Physics and Cosmology 1465 17 Temperature and Heat 554 APPENDICES 18 Thermal Properties of Matter 592 A The International System of Units 1509 19 The First Law of Thermodynamics 626 B Useful Mathematical Relations 1511 20 The Second Law of Thermodynamics 653 C The Greek Alphabet 1512 D Periodic Table of Elements 1513 Electromagnetism E Unit Conversion Factors 1514 21 F Numerical Constants 1515 Electric Charge and Electric Field 688 Answers to Odd-Numbered Problems 1517 22 Gauss’s Law 728 23 Electric Potential 758 INDEX 1530 Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page vi DETAILED CONTENTS Problem-Solving Strategies xii 4.3 Newton’s Second Law 112 Preface xiii 4.4 Mass and Weight 117 About the Authors xix 4.5 Newton’s Third Law 120 Acknowledgements xx 4.6 Free-Body Diagrams 123 Summary 126 Exercises/Problems 127 5 MECHANICS APPLYING NEWTON’S LAWS 132 5.1 Using Newton’s First Law: 1 UNITS, PHYSICAL Particles in Equilibrium 132 QUANTITIES AND VECTORS 1 5.2 Using Newton’s Second Law: 1.1 The Nature of Physics 2 Dynamics of Particles 138 1.2 Solving Physics Problems 2 5.3 Frictional Forces 145 1.3 Standards and Units 4 5.4 Dynamics of Circular Motion 154 1.4 Unit Consistency and Conversions 6 *5.5 The Fundamental Forces of Nature 159 1.5 Uncertainty and Significant Figures 8 Summary 161 1.6 Estimates and Orders of Magnitude 10 Exercises/Problems 162 1.7 Vectors and Vector Addition 11 1.8 Components of Vectors 15 6 WORK AND KINETIC ENERGY 175 1.9 Unit Vectors 20 1.10 Products of Vectors 21 6.1 Work 176 Summary 27 6.2 Kinetic Energy and the Work–Energy Exercises/Problems 28 Theorem 180 6.3 Work and Energy with Varying Forces 186 2 MOTION ALONG 6.4 Power 193 A STRAIGHT LINE 34 Summary 196 Exercises/Problems 197 2.1 Displacement, Time and Average Velocity 35 2.2 Instantaneous Velocity 37 2.3 Average and Instantaneous Acceleration 41 7 POTENTIAL ENERGY 2.4 Motion with Constant Acceleration 45 AND ENERGY CONSERVATION 205 2.5 Freely Falling Bodies 51 7.1 Gravitational Potential Energy 206 *2.6 Velocity and Position by Integration 55 7.2 Elastic Potential Energy 214 Summary 58 7.3 Conservative and Nonconservative Forces 220 Exercises/Problems 59 7.4 Force and Potential Energy 224 7.5 Energy Diagrams 227 3 MOTION IN TWO Summary 229 OR THREE DIMENSIONS 69 Exercises/Problems 230 3.1 Position and Velocity Vectors 70 3.2 The Acceleration Vector 72 8 MOMENTUM, IMPULSE 3.3 Projectile Motion 77 AND COLLISIONS 238 3.4 Motion in a Circle 85 8.1 Momentum and Impulse 238 3.5 Relative Velocity 89 Summary 94 8.2 Conservation of Momentum 244 Exercises/Problems 95 8.3 Momentum Conservation and Collisions 248 8.4 Elastic Collisions 253 4 8.5 Centre of Mass 257 NEWTON’S LAWS OF MOTION 104 *8.6 Rocket Propulsion 261 4.1 Force and Interactions 105 Summary 264 4.2 Newton’s First Law 108 Exercises/Problems 265 Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page vii Detailed Contents vii 9 13.3 Energy in Simple Harmonic Motion 416 ROTATION OF RIGID BODIES 275 13.4 Applications of Simple Harmonic Motion 420 9.1 Angular Velocity and Acceleration 275 13.5 The Simple Pendulum 424 9.2 Rotation with Constant Angular 13.6 The Physical Pendulum 426 Acceleration 280 13.7 Damped Oscillations 428 9.3 Relating Linear and Angular Kinematics 283 13.8 Forced Oscillations and Resonance 430 9.4 Energy in Rotational Motion 286 9.5 Parallel-Axis Theorem 291 Summary 433 *9.6 Moment-of-Inertia Calculations 293 Exercises/Problems 435 Summary 296 Exercises/Problems 297 14 FLUID MECHANICS 444 14.1 Density 444 10 DYNAMICS OF ROTATIONAL 14.2 Pressure in a Fluid 446 MOTION 305 14.3 Buoyancy 451 10.1 Torque 305 14.4 Fluid Flow 454 10.2 Torque and Angular Acceleration 14.5 Bernoulli’s Equation 456 for a Rigid Body 308 *14.6 Viscosity and Turbulence 460 10.3 Rigid-Body Rotation About a Moving Axis 312 Summary 463 10.4 Work and Power in Rotational Motion 318 Exercises/Problems 464 10.5 Angular Momentum 320 10.6 Conservation of Angular Momentum 322 10.7 Gyroscopes and Precession 326 Summary 330 WAVES/ACOUSTICS Exercises/Problems 332 15 MECHANICAL WAVES 472 11 EQUILIBRIUM AND ELASTICITY 342 15.1 Types of Mechanical Waves 473 11.1 Conditions for Equilibrium 343 15.2 Periodic Waves 474 11.2 Centre of Gravity 343 15.3 Mathematical Description of a Wave 477 11.3 Solving Rigid-Body Equilibrium Problems 346 15.4 Speed of a Transverse Wave 483 11.4 Stress, Strain and Elastic Moduli 351 15.5 Energy in Wave Motion 487 11.5 Elasticity and Plasticity 356 15.6 Wave Interference, Boundary Conditions Summary 358 and Superposition 490 Exercises/Problems 359 15.7 Standing Waves on a String 492 15.8 Normal Modes of a String 496 12 Summary 501 GRAVITATION 371 Exercises/Problems 503 12.1 Newton’s Law of Gravitation 371 12.2 Weight 376 16 SOUND AND HEARING 511 12.3 Gravitational Potential Energy 378 12.4 The Motion of Satellites 381 16.1 Sound Waves 511 12.5 Kepler’s Laws and the Motion of Planets 384 16.2 Speed of Sound Waves 516 *12.6 Spherical Mass Distributions 388 16.3 Sound Intensity 521 *12.7 Apparent Weight and the Earth’s Rotation 391 16.4 Standing Sound Waves and Normal 12.8 Black Holes 393 Modes 525 Summary 398 16.5 Resonance and Sound 530 Exercises/Problems 399 16.6 Interference of Waves 532 16.7 Beats 534 13 16.8 The Doppler Effect 536 PERIODIC MOTION 407 *16.9 Shock Waves 542 13.1 Describing Oscillation 407 Summary 545 13.2 Simple Harmonic Motion 409 Exercises/Problems 547 Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page viii viii Detailed Contents THERMODYNAMICS ELECTROMAGNETISM 17 TEMPERATURE AND HEAT 554 21 ELECTRIC CHARGE AND ELECTRIC FIELD 688 17.1 Temperature and Thermal Equilibrium 555 17.2 Thermometers and Temperature Scales 556 21.1 Electric Charge 689 17.3 Gas Thermometers and the Kelvin Scale 557 21.2 Conductors, Insulators and Induced Charges 692 17.4 Thermal Expansion 559 21.3 Coulomb’s Law 695 17.5 Quantity of Heat 565 21.4 Electric Field and Electric Forces 700 17.6 Calorimetry and Phase Changes 569 21.5 Electric-Field Calculations 706 21.6 Electric Field Lines 712 17.7 Mechanisms of Heat Transfer 575 21.7 Electric Dipoles 714 Summary 582 Summary 718 Exercises/Problems 584 Exercises/Problems 720 18 THERMAL PROPERTIES 22 GAUSS’S LAW 728 OF MATTER 592 22.1 Charge and Electric Flux 728 18.1 Equations of State 593 22.2 Calculating Electric Flux 731 18.2 Molecular Properties of Matter 599 22.3 Gauss’s Law 735 18.3 Kinetic-Molecular Model of an Ideal Gas 601 22.4 Applications of Gauss’s Law 739 18.4 Heat Capacities 608 22.5 Charges on Conductors 745 *18.5 Molecular Speeds 611 Summary 750 18.6 Phases of Matter 613 Exercises/Problems 751 Summary 617 23 Exercises/Problems 619 ELECTRIC POTENTIAL 758 23.1 Electric Potential Energy 758 19 THE FIRST LAW OF 23.2 Electric Potential 765 THERMODYNAMICS 626 23.3 Calculating Electric Potential 772 19.1 Thermodynamic Systems 626 23.4 Equipotential Surfaces 776 19.2 Work Done During Volume Changes 627 23.5 Potential Gradient 779 19.3 Paths Between Thermodynamic States 630 Summary 782 19.4 Internal Energy and the First Law of Exercises/Problems 783 Thermodynamics 631 19.5 Kinds of Thermodynamic Processes 636 24 CAPACITANCE 19.6 Internal Energy of an Ideal Gas 638 AND DIELECTRICS 791 19.7 Heat Capacities of an Ideal Gas 639 24.1 Capacitors and Capacitance 792 19.8 Adiabatic Processes for an Ideal Gas 642 24.2 Capacitors in Series and Parallel 796 Summary 645 24.3 Energy Storage in Capacitors Exercises/Problems 647 and Electric-Field Energy 800 24.4 Dielectrics 804 20 THE SECOND LAW OF *24.5 Molecular Model of Induced Charge 809 THERMODYNAMICS 653 *24.6 Gauss’s Law in Dielectrics 811 Summary 813 20.1 Directions of Thermodynamic Processes 653 Exercises/Problems 814 20.2 Heat Engines 655 20.3 Internal-Combustion Engines 658 25 CURRENT, RESISTANCE AND 20.4 Refrigerators 660 ELECTROMOTIVE FORCE 822 20.5 The Second Law of Thermodynamics 662 20.6 The Carnot Cycle 664 25.1 Current 823 20.7 Entropy 670 25.2 Resistivity 826 *20.8 Microscopic Interpretation of Entropy 677 25.3 Resistance 829 Summary 680 25.4 Electromotive Force and Circuits 833 Exercises/Problems 682 25.5 Energy and Power in Electric Circuits 839 Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition youn.187x.FMext.pgs 14/5/10 1:52 PM Page ix Detailed Contents ix *25.6 Theory of Metallic Conduction 843 *29.8 Superconductivity 985 Summary 847 Summary 987 Exercises/Problems 849 Exercises/Problems 988 26 30 DIRECT-CURRENT CIRCUITS 855 INDUCTANCE 996 26.1 Resistors in Series and Parallel 855 30.1 Mutual Inductance 996 26.2 Kirchhoff’s Rules 860 30.2 Self-Inductance and Inductors 1000 26.3 Electrical Measuring Instruments 865 30.3 Inductors and Magnetic-Field Energy 1004 26.4 R-CCircuits 870 30.4 The R-LCircuit 1007 26.5 Power Distribution Systems 874 30.5 The L-CCircuit 1011 Summary 877 30.6 The L-R-CSeries Circuit 1015 Exercises/Problems 878 Summary 1018 Exercises/Problems 1019 27 MAGNETIC FIELD 31 AND MAGNETIC FORCES 886 ALTERNATING CURRENT 1026 27.1 Magnetism 886 31.1 Phasors and Alternating Currents 1026 27.2 Magnetic Field 888 31.2 Resistance and Reactance 1029 27.3 Magnetic Field Lines and Magnetic Flux 892 31.3 The L-R-CSeries Circuit 1035 27.4 Motion of Charged Particles 31.4 Power in Alternating-Current Circuits 1039 in a Magnetic Field 895 31.5 Resonance in Alternating-Current Circuits 1042 27.5 Applications of Motion of Charged Particles 899 31.6 Transformers 1045 27.6 Magnetic Force on a Summary 1049 Current-Carrying Conductor 902 Exercises/Problems 1050 27.7 Force and Torque on a Current Loop 905 *27.8 The Direct-Current Motor 911 32 *27.9 The Hall Effect 913 ELECTROMAGNETIC WAVES 1056 Summary 915 32.1 Maxwell’s Equations Exercises/Problems 917 and Electromagnetic Waves 1057 28 32.2 Plane Electromagnetic Waves SOURCES OF MAGNETIC FIELD 926 and the Speed of Light 1060 32.3 Sinusoidal Electromagnetic Waves 1065 28.1 Magnetic Field of a Moving Charge 926 32.4 Energy and Momentum 28.2 Magnetic Field of a Current Element 929 in Electromagnetic Waves 1070 28.3 Magnetic Field of a Straight 32.5 Standing Electromagnetic Waves 1075 Current-Carrying Conductor 931 Summary 1079 28.4 Force Between Parallel Conductors 934 28.5 Magnetic Field of a Circular Current Loop 936 Exercises/Problems 1080 28.6 Ampere’s Law 938 28.7 Applications of Ampere’s Law 942 *28.8 Magnetic Materials 945 OPTICS Summary 951 Exercises/Problems 953 33 THE NATURE AND 29 ELECTROMAGNETIC PROPAGATION OF LIGHT 1085 INDUCTION 961 33.1 The Nature of Light 1085 29.1 Induction Experiments 962 33.2 Reflection and Refraction 1087 29.2 Faraday’s Law 964 33.3 Total Internal Reflection 1093 29.3 Lenz’s Law 972 *33.4 Dispersion 1096 29.4 Motional Electromotive Force 974 33.5 Polarisation 1097 29.5 Induced Electric Fields 976 *33.6 Scattering of Light 1106 *29.6 Eddy Currents 979 33.7 Huygens’s Principle 1108 29.7 Displacement Current Summary 1111 and Maxwell’s Equations 981 Exercises/Problems 1113 Copyright © Pearson Australia (a division of Pearson Australia Group Pty Ltd) 2011 – 9781442517110 - Young/University Physics 1st edition