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  • ISBN-10 ‏ : ‎ 1133110932
  • ISBN-13 ‏ : ‎ 978-1133110934
  • Author;  Raymond A. Serway, John W. Jewett

PRINCIPLES OF PHYSICS features a concise approach to traditional topics, an early introduction to modern physics, and integration of physics education research pedagogy, as well as the inclusion of contemporary topics throughout the text. This revision of PRINCIPLES OF PHYSICS also contains a new worked example format, two new Contexts features, a revised problem set based on an analysis of problem usage data from WebAssign, and a thorough revision of every piece of line art in the text. This hybrid version features the same content and coverage as the full text along with our integrated digital homework solution, Enhanced WebAssign. Now your students can have a more interactive learning experience, with the convenience of a text that is both brief and affordable.

 

Table of Content:

  1. Ch 1: Introduction and Vectors
  2. 1.1 Standards of Length, Mass, and Time
  3. 1.2 Dimensional Analysis
  4. 1.3 Conversion of Units
  5. 1.4 Order-of-Magnitude Calculations
  6. 1.5 Significant Figures
  7. 1.6 Coordinate Systems
  8. 1.7 Vectors and Scalars
  9. 1.8 Some Properties of Vectors
  10. 1.9 Components of a Vector and Unit Vectors
  11. 1.10 Modeling, Alternative Representations, and Problem-Solving Strategy
  12. Summary
  13. Objective Questions
  14. Conceptual Questions
  15. Problems
  16. Context 1: Alternative-Fuel Vehicles
  17. Ch 2: Motion in One Dimension
  18. 2.1 Average Velocity
  19. 2.2 Instantaneous Velocity
  20. 2.3 Analysis Model: Particle under Constant Velocity
  21. 2.4 Acceleration
  22. 2.5 Motion Diagrams
  23. 2.6 Analysis Model: Particle under Constant Acceleration
  24. 2.7 Freely Falling Objects
  25. 2.8 Context Connection: Acceleration Required by Consumers
  26. Summary
  27. Objective Questions
  28. Conceptual Questions
  29. Problems
  30. Ch 3: Motion in Two Dimensions
  31. 3.1 The Position, Velocity, and Acceleration Vectors
  32. 3.2 Two-Dimensional Motion with Constant Acceleration
  33. 3.3 Projectile Motion
  34. 3.4 Analysis Model: Particle in Uniform Circular Motion
  35. 3.5 Tangential and Radial Acceleration
  36. 3.6 Relative Velocity and Relative Acceleration
  37. 3.7 Context Connection: Lateral Acceleration of Automobiles
  38. Summary
  39. Objective Questions
  40. Conceptual Questions
  41. Problems
  42. Ch 4: The Laws of Motion
  43. 4.1 The Concept of Force
  44. 4.2 Newton’s First Law
  45. 4.3 Mass
  46. 4.4 Newton’s Second Law
  47. 4.5 The Gravitational Force and Weight
  48. 4.6 Newton’s Third Law
  49. 4.7 Analysis Models Using Newton’s Second Law
  50. 4.8 Context Connection: Forces on Automobiles
  51. Summary
  52. Objective Questions
  53. Conceptual Questions
  54. Problems
  55. Ch 5: More Applications of Newton’s Laws
  56. 5.1 Forces of Friction
  57. 5.2 Extending the Particle in Uniform Circular Motion Model
  58. 5.3 Nonuniform Circular Motion
  59. 5.4 Motion in the Presence of Velocity-Dependent Resistive Forces
  60. 5.5 The Fundamental Forces of Nature
  61. 5.6 Context Connection: Drag Coefficients of Automobiles
  62. Summary
  63. Objective Questions
  64. Conceptual Questions
  65. Problems
  66. Ch 6: Energy of a System
  67. 6.1 Systems and Environments
  68. 6.2 Work Done by a Constant Force
  69. 6.3 The Scalar Product of Two Vectors
  70. 6.4 Work Done by a Varying Force
  71. 6.5 Kinetic Energy and the Work-Kinetic Energy Theorem
  72. 6.6 Potential Energy of a System
  73. 6.7 Conservative and Nonconservative Forces
  74. 6.8 Relationship between Conservative Forces and Potential Energy
  75. 6.9 Potential Energy for Gravitational and Electric Forces
  76. 6.10 Energy Diagrams and Equilibrium of a System
  77. 6.11 Context Connection: Potential Energy in Fuels
  78. Summary
  79. Objective Questions
  80. Conceptual Questions
  81. Problems
  82. Ch 7: Conservation of Energy
  83. 7.1 Analysis Model: Nonisolated System (Energy)
  84. 7.2 Analysis Model: Isolated System (Energy)
  85. 7.3 Analysis Model: Nonisolated System in Steady State (Energy)
  86. 7.4 Situations Involving Kinetic Friction
  87. 7.5 Changes in Mechanical Energy for Nonconservative Forces
  88. 7.6 Power
  89. 7.7 Context Connection: Horsepower Ratings of Automobiles
  90. Summary
  91. Objective Questions
  92. Conceptual Questions
  93. Problems
  94. Context 1: Present and Future Possibilities
  95. Context 2: Mission to Mars
  96. Ch 8: Momentum and Collisions
  97. 8.1 Linear Momentum
  98. 8.2 Analysis Model: Isolated System (Momentum)
  99. 8.3 Analysis Model: Nonisolated System (Momentum)
  100. 8.4 Collisions in One Dimension
  101. 8.5 Collisions in Two Dimensions
  102. 8.6 The Center of Mass
  103. 8.7 Motion of a System of Particles
  104. 8.8 Context Connection: Rocket Propulsion
  105. Summary
  106. Objective Questions
  107. Conceptual Questions
  108. Problems
  109. Ch 9: Relativity
  110. 9.1 The Principle of Galilean Relativity
  111. 9.2 The Michelson-Morley Experiment
  112. 9.3 Einstein’s Principle of Relativity
  113. 9.4 Consequences of Special Relativity
  114. 9.5 The Lorentz Transformation Equations
  115. 9.6 Relativistic Momentum and the Relativistic Form of Newton’s Laws
  116. 9.7 Relativistic Energy
  117. 9.8 Mass and Energy
  118. 9.9 General Relativity
  119. 9.10 Context Connection: From Mars to the Stars
  120. Summary
  121. Objective Questions
  122. Conceptual Questions
  123. Problems
  124. Ch 10: Rotational Motion
  125. 10.1 Angular Position, Speed, and Acceleration
  126. 10.2 Analysis Model: Rigid Object under Constant Angular Acceleration
  127. 10.3 Relations between Rotational and Translational Quantities
  128. 10.4 Rotational Kinetic Energy
  129. 10.5 Torque and the Vector Product
  130. 10.6 Analysis Model: Rigid Object in Equilibrium
  131. 10.7 Analysis Model: Rigid Object under a Net Torque
  132. 10.8 Energy Considerations in Rotational Motion
  133. 10.9 Analysis Model: Nonisolated System (Angular Momentum)
  134. 10.10 Analysis Model: Isolated System (Angular Momentum)
  135. 10.11 Precessional Motion of Gyroscopes
  136. 10.12 Rolling Motion of Rigid Objects
  137. 10.13 Context Connection: Turning the Spacecraft
  138. Summary
  139. Objective Questions
  140. Conceptual Questions
  141. Problems
  142. Ch 11: Gravity, Planetary Orbits, and the Hydrogen Atom
  143. 11.1 Newton’s Law of Universal Gravitation Revisited
  144. 11.2 Structural Models
  145. 11.3 Kepler’s Laws
  146. 11.4 Energy Considerations in Planetary and Satellite Motion
  147. 11.5 Atomic Spectra and the Bohr Theory of Hydrogen
  148. 11.6 Context Connection: Changing from a Circular to an Elliptical Orbit
  149. Summary
  150. Objective Questions
  151. Conceptual Questions
  152. Problems
  153. Ch 12: Oscillatory Motion
  154. 12.1 Motion of an Object Attached to a Spring
  155. 12.2 Analysis Model: Particle in Simple Harmonic Motion
  156. 12.3 Energy of the Simple Harmonic Oscillator
  157. 12.4 The Simple Pendulum
  158. 12.5 The Physical Pendulum
  159. 12.6 Damped Oscillations
  160. 12.7 Forced Oscillations
  161. 12.8 Context Connection: Resonance in Structures
  162. Summary
  163. Objective Questions
  164. Conceptual Questions
  165. Problems
  166. Ch 13: Mechanical Waves
  167. 13.1 Propagation of a Disturbance
  168. 13.2 Analysis Model: Traveling Wave
  169. 13.3 The Speed of Transverse Waves on Strings
  170. 13.4 Reflection and Transmission
  171. 13.5 Rate of Energy Transfer by Sinusoidal Waves on Strings
  172. 13.6 Sound Waves
  173. 13.7 The Doppler Effect
  174. 13.8 Context Connection: Seismic Waves
  175. Summary
  176. Objective Questions
  177. Conceptual Questions
  178. Problems
  179. Ch 14: Superposition and Standing Waves
  180. 14.1 Analysis Model: Waves in Interference
  181. 14.2 Standing Waves
  182. 14.3 Analysis Model: Waves under Boundary Conditions
  183. 14.4 Standing Waves in Air Columns
  184. 14.5 Beats: Interference in Time
  185. 14.6 Nonsinusoidal Wave Patterns
  186. 14.7 The Ear and Theories of Pitch Perception: BIO
  187. 14.8 Context Connection: Building on Antinodes
  188. Summary
  189. Objective Questions
  190. Conceptual Questions
  191. Problems
  192. Context 3: Conclusion: Minimizing the Risk
  193. Context 4: Heart Attacks
  194. Ch 15: Fluid Mechanics
  195. 15.1 Pressure
  196. 15.2 Variation of Pressure with Depth
  197. 15.3 Pressure Measurements
  198. 15.4 Buoyant Forces and Archimedes’s Principle
  199. 15.5 Fluid Dynamics
  200. 15.6 Streamlines and the Continuity Equation for Fluids
  201. 15.7 Bernoulli’s Equation
  202. 15.8 Other Applications of Fluid Dynamics
  203. 15.9 Context Connection: Turbulent Flow of Blood
  204. Summary
  205. Objective Questions
  206. Conceptual Questions
  207. Problems
  208. Context 4: Conclusion: Detecting Atherosclerosis and Preventing Heart Attacks
  209. Context 5: Global Warming
  210. Ch 16: Temperature and the Kinetic Theory of Gases
  211. 16.1 Temperature and the Zeroth Law of Thermodynamics
  212. 16.2 Thermometers and Temperature Scales
  213. 16.3 Thermal Expansion of Solids and Liquids
  214. 16.4 Macroscopic Description of an Ideal Gas
  215. 16.5 The Kinetic Theory of Gases
  216. 16.6 Distribution of Molecular Speeds
  217. 16.7 Context Connection: The Atmospheric Lapse Rate
  218. Summary
  219. Objective Questions
  220. Conceptual Questions
  221. Problems
  222. Ch 17: Energy in Thermal Processes: The First Law of Thermodynamics
  223. 17.1 Heat and Internal Energy
  224. 17.2 Specific Heat
  225. 17.3 Latent Heat
  226. 17.4 Work in Thermodynamic Processes
  227. 17.5 The First Law of Thermodynamics
  228. 17.6 Some Applications of the First Law of Thermodynamics
  229. 17.7 Molar Specific Heats of Ideal Gases
  230. 17.8 Adiabatic Processes for an Ideal Gas
  231. 17.9 Molar Specific Heats and the Equipartition of Energy
  232. 17.10 Energy Transfer Mechanisms in Thermal Processes
  233. 17.11 Context Connection: Energy Balance for the Earth
  234. Summary
  235. Objective Questions
  236. Conceptual Questions
  237. Problems
  238. Ch 18: Heat Engines, Entropy, and the Second Law of Thermodynamics
  239. 18.1 Heat Engines and the Second Law of Thermodynamics
  240. 18.2 Reversible and Irreversible Processes
  241. 18.3 The Carnot Engine
  242. 18.4 Heat Pumps and Refrigerators
  243. 18.5 An Alternative Statement of the Second Law
  244. 18.6 Entropy
  245. 18.7 Entropy and the Second Law of Thermodynamics
  246. 18.8 Entropy Changes in Irreversible Processes
  247. 18.9 Context Connection: The Atmosphere as a Heat Engine
  248. Summary
  249. Objective Questions
  250. Conceptual Questions
  251. Problems
  252. Context 5: Conclusion: Predicting the Earth’s Surface Temperature
  253. Context 6: Lightning
  254. Ch 19: Electric Forces and Electric Fields
  255. 19.1 Historical Overview
  256. 19.2 Properties of Electric Charges
  257. 19.3 Insulators and Conductors
  258. 19.4 Coulomb’s Law
  259. 19.5 Electric Fields
  260. 19.6 Electric Field Lines
  261. 19.7 Motion of Charged Particles in a Uniform Electric Field
  262. 19.8 Electric Flux
  263. 19.9 Gauss’s Law
  264. 19.10 Application of Gauss’s Law to Various Charge Distributions
  265. 19.11 Conductors in Electrostatic Equilibrium
  266. 19.12 Context Connection: The Atmospheric Electric Field
  267. Summary
  268. Objective Questions
  269. Conceptual Questions
  270. Problems
  271. Ch 20: Electric Potential and Capacitance
  272. 20.1 Electric Potential and Potential Difference
  273. 20.2 Potential Difference in a Uniform Electric Field
  274. 20.3 Electric Potential and Potential Energy Due to Point Charges
  275. 20.4 Obtaining the Value of the Electric Field from the Electric Potential
  276. 20.5 Electric Potential Due to Continuous Charge Distributions
  277. 20.6 Electric Potential Due to a Charged Conductor
  278. 20.7 Capacitance
  279. 20.8 Combinations of Capacitors
  280. 20.9 Energy Stored in a Charged Capacitor
  281. 20.10 Capacitors with Dielectrics
  282. 20.11 Context Connection: The Atmosphere as a Capacitor
  283. Summary
  284. Objective Questions
  285. Conceptual Questions
  286. Problems
  287. Ch 21: Current and Direct Current Circuits
  288. 21.1 Electric Current
  289. 21.2 Resistance and Ohm’s Law
  290. 21.3 Superconductors
  291. 21.4 A Model for Electrical Conduction
  292. 21.5 Energy and Power in Electric Circuits
  293. 21.6 Sources of emf
  294. 21.7 Resistors in Series and Parallel
  295. 21.8 Kirchhoff ‘s Rules
  296. 21.9 RC Circuits
  297. 21.10 Context Connection: The Atmosphere as a Conductor
  298. Summary
  299. Objective Questions
  300. Conceptual Questions
  301. Problems
  302. Context 6: Conclusion: Determining the Number of Lightning Strikes
  303. Context 7: Magnetism in Medicine
  304. Ch 22: Magnetic Forces and Magnetic Fields
  305. 22.1 Historical Overview
  306. 22.2 The Magnetic Field
  307. 22.3 Motion of a Charged Particle in a Uniform Magnetic Field
  308. 22.4 Applications Involving Charged Particles Moving in a Magnetic Field
  309. 22.5 Magnetic Force on a Current-Carrying Conductor
  310. 22.6 Torque on a Current Loop in a Uniform Magnetic Field
  311. 22.7 The Biot-Savart Law
  312. 22.8 The Magnetic Force between Two Parallel Conductors
  313. 22.9 Ampere’s Law
  314. 22.10 The Magnetic Field of a Solenoid
  315. 22.11 Magnetism in Matter
  316. 22.12 Context Connection: Remote Magnetic Navigation for Cardiac Catheter Ablation Procedures
  317. Summary
  318. Objective Questions
  319. Conceptual Questions
  320. Problems
  321. Ch 23: Faraday’s Law and Inductance
  322. 23.1 Faraday’s Law of Induction
  323. 23.2 Motional emf
  324. 23.3 Lenz’s Law
  325. 23.4 Induced emfs and Electric Fields
  326. 23.5 Inductance
  327. 23.6 RL Circuits
  328. 23.7 Energy Stored in a Magnetic Field
  329. 23.8 Context Connection: The Use of Transcranial Magnetic Stimulation in Depression: BIO
  330. Summary
  331. Objective Questions
  332. Conceptual Questions
  333. Problems
  334. Context 7: Conclusion: Nuclear Magnetic Resonance and Magnetic Resonance Imaging
  335. Context 8: Lasers
  336. Ch 24: Electromagnetic Waves
  337. 24.1 Displacement Current and the Generalized Form of Ampere’s Law
  338. 24.2 Maxwell’s Equations and Hertz’s Discoveries
  339. 24.3 Electromagnetic Waves
  340. 24.4 Energy Carried by Electromagnetic Waves
  341. 24.5 Momentum and Radiation Pressure
  342. 24.6 The Spectrum of Electromagnetic Waves
  343. 24.7 Polarization of Light Waves
  344. 24.8 Context Connection: The Special Properties of Laser Light
  345. Summary
  346. Objective Questions
  347. Conceptual Questions
  348. Problems
  349. Ch 25: Reflection and Refraction of Light
  350. 25.1 The Nature of Light
  351. 25.2 The Ray Model in Geometric Optics
  352. 25.3 Analysis Model: Wave under Reflection
  353. 25.4 Analysis Model: Wave under Refraction
  354. 25.5 Dispersion and Prisms
  355. 25.6 Huygens’s Principle
  356. 25.7 Total Internal Reflection
  357. 25.8 Context Connection: Optical Fibers
  358. Summary
  359. Objective Questions
  360. Conceptual Questions
  361. Problems
  362. Ch 26: Image Formation by Mirrors and Lenses
  363. 26.1 Images Formed by Flat Mirrors
  364. 26.2 Images Formed by Spherical Mirrors
  365. 26.3 Images Formed by Refraction
  366. 26.4 Images Formed by Thin Lenses
  367. 26.5 The Eye: BIO
  368. 26.6 Context Connection: Some Medical Applications: BIO
  369. Summary
  370. Objective Questions
  371. Conceptual Questions
  372. Problems
  373. Ch 27: Wave Optics
  374. 27.1 Conditions for Interference
  375. 27.2 Young’s Double-Slit Experiment
  376. 27.3 Analysis Model: Waves in Interference
  377. 27.4 Change of Phase Due to Reflection
  378. 27.5 Interference in Thin Films
  379. 27.6 Diffraction Patterns
  380. 27.7 Resolution of Single-Slit and Circular Apertures
  381. 27.8 The Diffraction Grating
  382. 27.9 Diffraction of X-Rays by Crystals
  383. 27.10 Context Connection: Holography
  384. Summary
  385. Objective Questions
  386. Conceptual Questions
  387. Problems
  388. Context 8: Conclusion: Using Lasers to Record and Read Digital Information
  389. Context 9: The Cosmic Connection
  390. Ch 28: Quantum Physics
  391. 28.1 Blackbody Radiation and Planck’s Theory
  392. 28.2 The Photoelectric Effect
  393. 28.3 The Compton Effect
  394. 28.4 Photons and Electromagnetic Waves
  395. 28.5 The Wave Properties of Particles
  396. 28.6 A New Model: The Quantum Particle
  397. 28.7 The Double-Slit Experiment Revisited
  398. 28.8 The Uncertainty Principle
  399. 28.9 An Interpretation of Quantum Mechanics
  400. 28.10 A Particle in a Box
  401. 28.11 Analysis Model: Quantum Particle under Boundary Conditions
  402. 28.12 The Schrodinger Equation
  403. 28.13 Tunneling through a Potential Energy Barrier
  404. 28.14 Context Connection: The Cosmic Temperature
  405. Summary
  406. Objective Questions
  407. Conceptual Questions
  408. Problems
  409. Ch 29: Atomic Physics
  410. 29.1 Early Structural Models of the Atom
  411. 29.2 The Hydrogen Atom Revisited
  412. 29.3 The Wave Functions for Hydrogen
  413. 29.4 Physical Interpretation of the Quantum Numbers
  414. 29.5 The Exclusion Principle and the Periodic Table
  415. 29.6 More on Atomic Spectra: Visible and X-Ray
  416. 29.7 Context Connection: Atoms in Space
  417. Summary
  418. Objective Questions
  419. Conceptual Questions
  420. Problems
  421. Ch 30: Nuclear Physics
  422. 30.1 Some Properties of Nuclei
  423. 30.2 Nuclear Binding Energy
  424. 30.3 Radioactivity
  425. 30.4 The Radioactive Decay Processes
  426. 30.5 Nuclear Reactions
  427. 30.6 Context Connection: The Engine of the Stars
  428. Summary
  429. Objective Questions
  430. Conceptual Questions
  431. Problems
  432. Ch 31: Particle Physics
  433. 31.1 The Fundamental Forces in Nature
  434. 31.2 Positrons and Other Antiparticles
  435. 31.3 Mesons and the Beginning of Particle Physics
  436. 31.4 Classification of Particles
  437. 31.5 Conservation Laws
  438. 31.6 Strange Particles and Strangeness
  439. 31.7 Measuring Particle Lifetimes
  440. 31.8 Finding Patterns in the Particles
  441. 31.9 Quarks
  442. 31.10 Multicolored Quarks
  443. 31.11 The Standard Model
  444. 31.12 Context Connection: Investigating the Smallest System to Understand the Largest
  445. Summary
  446. Objective Questions
  447. Conceptual Questions
  448. Problems
  449. Context 9: Conclusion: Problems and Perspectives
  450. Appendix A: Tables
  451. Appendix B: Mathematics Review
  452. B.1 Scientific Notation
  453. B.2 Algebra
  454. B.3 Geometry
  455. B.4 Trigonometry
  456. B.5 Series Expansions
  457. B.6 Differential Calculus
  458. B.7 Integral Calculus
  459. B.8 Propagation of Uncertainty
  460. Appendix C: Periodic Table of the Elements
  461. Appendix D: SI Units
  462. Answers to Quick Quizzes and Odd-Numbered Problems
  463. Index

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