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Physics for scientists and engineers with modern physics /

Record Type:	Language materials, printed : Monograph/item
Title/Author:	Physics for scientists and engineers with modern physics // Raymond A. Serway, John W. Jewett, Jr. ; with contributions from Vahé Peroomian.
Author:	Serway, Raymond A.
other author:	Jewett, John W.
Published:	Boston, MA :Brooks/Cole, Cengage Learning, : 2014.,
Description:	xxxii, 1484, [95] p. :ill. (chiefly col.), ports. (some col.) ; : 28 cm.;
Notes:	Includes index.
Subject:	Physics -
ISBN:	9781133953999 (pbk.) :

Physics for scientists and engineers with modern physics /
Serway, Raymond A.

Physics for scientists and engineers with modern physics /Raymond A. Serway, John W. Jewett, Jr. ; with contributions from Vahé Peroomian. - 9th ed., International ed. - Boston, MA :Brooks/Cole, Cengage Learning,2014. - xxxii, 1484, [95] p. :ill. (chiefly col.), ports. (some col.) ;28 cm.

Includes index.

Machine generated contents note: pt. 1 Mechanics -- 1.Physics and Measurement -- 1.1.Standards of Length, Mass, and Time -- 1.2.Matter and Model Building -- 1.3.Dimensional Analysis -- 1.4.Conversion of Units -- 1.5.Estimates and Order-of-Magnitude Calculations -- 1.6.Significant Figures -- 2.Motion in One Dimension -- 2.1.Position, Velocity, and Speed -- 2.2.Instantaneous Velocity and Speed -- 2.3.Analysis Model: Particle Under Constant Velocity -- 2.4.Acceleration -- 2.5.Motion Diagrams -- 2.6.Analysis Model: Particle Under Constant Acceleration -- 2.7.Freely Falling Objects -- 2.8.Kinematic Equations Derived from Calculus -- 3.Vectors -- 3.1.Coordinate Systems -- 3.2.Vector and Scalar Quantities -- 3.3.Some Properties of Vectors -- 3.4.Components of a Vector and Unit Vectors -- 4.Motion in Two Dimensions -- 4.1.The Position, Velocity, and Acceleration Vectors -- 4.2.Two-Dimensional Motion with Constant Acceleration -- 4.3.Projectile Motion -- 4.4.Analysis Model: Particle in Uniform Circular Motion -- 4.5.Tangential and Radial Acceleration -- 4.6.Relative Velocity and Relative Acceleration -- 5.The Laws of Motion -- 5.1.The Concept of Force -- 5.2.Newton's First Law and Inertial Frames -- 5.3.Mass -- 5.4.Newton's Second Law -- 5.5.The Gravitational Force and Weight -- 5.6.Newton's Third Law -- 5.7.Analysis Models Using Newton's Second Law -- 5.8.Forces of Friction -- 6.Circular Motion and Other Applications of Newton's Laws -- 6.1.Extending the Particle in Uniform Circular Motion Model -- 6.2.Nonuniform Circular Motion -- 6.3.Motion in Accelerated Frames -- 6.4.Motion in the Presence of Resistive Forces -- 7.Energy of a System -- 7.1.Systems and Environments -- 7.2.Work Done by a Constant Force -- 7.3.The Scalar Product of Two Vectors -- 7.4.Work Done by a Varying Force -- 7.5.Kinetic Energy and the Work-Kinetic Energy Theorem -- 7.6.Potential Energy of a System -- 7.7.Conservative and Nonconservative Forces -- 7.8.Relationship Between Conservative Forces and Potential Energy -- 7.9.Energy Diagrams and Equilibrium of a System -- 8.Conservation of Energy -- 8.1.Analysis Model: Nonisolated System (Energy) -- 8.2.Analysis Model: Isolated System (Energy) -- 8.3.Situations Involving Kinetic Friction -- 8.4.Changes in Mechanical Energy for Nonconservative Forces -- 8.5.Power -- 9.Linear Momentum and Collisions -- 9.1.Linear Momentum -- 9.2.Analysis Model: Isolated System (Momentum) -- 9.3.Analysis Model: Nonisolated System [Momentum] -- 9.4.Collisions in One Dimension -- 9.5.Collisions in Two Dimensions -- 9.6.The Center of Mass -- 9.7.Systems of Many Particles -- 9.8.Deformable Systems -- 9.9.Rocket Propulsion -- 10.Rotation of a Rigid Object About a Fixed Axis -- 10.1.Angular Position, Velocity, and Acceleration -- 10.2.Analysis Model: Rigid Object Under Constant Angular Acceleration -- 10.3.Angular and Translations! Quantities -- 10.4.Torque -- 10.5.Analysis Model: Rigid Object Under a Net Torque -- 10.6.Calculation of Moments of Inertia -- 10.7.Rotational Kinetic Energy -- 10.8.Energy Considerations in Rotational Motion -- 10.9.Rolling Motion of a Rigid Object -- 11.Angular Momentum -- 11.1.The Vector Product and Torque -- 11.2.Analysis Model: Nonisolated System (Angular Momentum) -- 11.3.Angular Momentum of a Rotating Rigid Object -- 11.4.Analysis Model: Isolated System (Angular Momentum) -- 11.5.The Motion of Gyroscopes and Tops -- 12.Static Equilibrium and Elasticity -- 12.1.Analysis Model: Rigid Object in Equilibrium -- 12.2.More on the Center of Gravity -- 12.3.Examples of Rigid Objects in Static Equilibrium -- 12.4.Elastic Properties of Solids -- 13.Universal Gravitation -- 13.1.Newton's Law of Universal Gravitation -- 13.2.Free-Fall Acceleration and the Gravitational Force -- 13.3.Analysis Model: Particle in a Field (Gravitational) -- 13.4.Kepler's Laws and the Motion of Planets -- 13.5.Gravitational Potential Energy -- 13.6.Energy Considerations in Planetary and Satellite Motion -- 14.Fluid Mechanics -- 14.1.Pressure -- 14.2.Variation of Pressure with Depth -- 14.3.Pressure Measurements -- 14.4.Buoyant Forces and Archimedes's Principle -- 14.5.Fluid Dynamics -- 14.6.Bernoulli's Equation -- 14.7.Other Applications of Fluid Dynamics -- pt. 2 Oscillations and Mechanical Waves -- 15.Oscillatory Motion -- 15.1.Motion of an Object Attached to a Spring -- 15.2.Analysis Model: Particle in Simple Harmonic Motion -- 15.3.Energy of the Simple Harmonic Oscillator -- 15.4.Comparing Simple Harmonic Motion with Uniform Circular Motion -- 15.5.The Pendulum -- 15.6.Damped Oscillations -- 15.7.Forced Oscillations -- 16.Wave Motion -- 16.1.Propagation of a Disturbance -- 16.2.Analysis Model: Traveling Wave -- 16.3.The Speed of Waves on Strings -- 16.4.Reflection and Transmission -- 16.5.Rate of Energy Transfer by Sinusoidal Waves on Strings -- 16.6.The Linear Wave Equation -- 17.Sound Waves -- 17.1.Pressure Variations in Sound Waves -- 17.2.Speed of Sound Waves -- 17.3.Intensity of Periodic Sound Waves -- 17.4.The Doppler Effect -- 18.Superposition and Standing Waves -- 18.1.Analysis Model: Waves in Interference -- 18.2.Standing Waves -- 18.3.Analysis Model: Waves Under Boundary Conditions -- 18.4.Resonance -- 18.5.Standing Waves in Air Columns -- 18.6.Standing Waves in Rods and Membranes -- 18.7.Beats: Interference in Time -- 18.8.Nonsinusoidal Wave Patterns -- pt. 3 Thermodynamics -- 19.Temperature -- 19.1.Temperature and the Zeroth Law of Thermodynamics -- 19.2.Thermometers and the Celsius Temperature Scale -- 19.3.The Constant-Volume Gas Thermometer and the Absolute Temperature Scale -- 19.4.Thermal Expansion of Solids and Liquids -- 19.5.Macroscopic Description of an Ideal Gas -- 20.The First Law of Thermodynamics -- 20.1.Heat and Internal Energy -- 20.2.Specific Heat and Calorimetry -- 20.3.Latent Heat -- 20.4.Work and Heat in Thermodynamic Processes -- 20.5.The First Law of Thermodynamics -- 20.6.Some Applications of the First Law of Thermodynamics -- 20.7.Energy Transfer Mechanisms in Thermal Processes -- 21.The Kinetic Theory of Gases -- 21.1.Molecular Mode! of an Ideal Gas -- 21.2.Molar Specific Heat of an Ideal Gas -- 21.3.The Equipartition of Energy -- 21.4.Adiabatic Processes for an Ideal Gas -- 21.5.Distribution of Molecular Speeds -- 22.Heat Engines, Entropy, and the Second Law of Thermodynamics -- 22.1.Heat Engines and the Second Law of Thermodynamics -- 22.2.Heat Pumps and Refrigerators -- 22.3.Reversible and Irreversible Processes -- 22.4.The Carnot Engine -- 22.5.Gasoline and Diesel Engines -- 22.6.Entropy -- 22.7.Changes in Entropy for Thermodynamic Systems -- 22.8.Entropy and the Second Law -- pt. 4 Electricity and Magnetism -- 23.Electric Fields -- 23.1.Properties of Electric Charges -- 23.2.Charging Objects by Induction -- 23.3.Coulomb's Law -- 23.4.Analysis Model: Particle in a Field [Electric] -- 23.5.Electric Field of a Continuous Charge Distribution -- 23.6.Electric Field Lines -- 23.7.Motion of a Charged Particle in a Uniform Electric Field -- 24.Gauss's Law -- 24.1.Electric Flux -- 24.2.Gauss's Law -- 24.3.Application of Gauss's Law to Various Charge Distributions -- 24.4.Conductors in Electrostatic Equilibrium -- 25.Electric Potential -- 25.1.Electric Potential and Potential Difference -- 25.2.Potential Difference in a Uniform Electric Field -- 25.3.Electric Potential and Potential Energy Due to Point Charges -- 25.4.Obtaining the Value of the Electric Field from the Electric Potential -- 25.5.Electric Potential Due to Continuous Charge Distributions -- 25.6.Electric Potential Due to a Charged Conductor -- 25.7.The Millikan Oil-Drop Experiment -- 25.8.Applications of Electrostatics -- 26.Capacitance and Dielectrics -- 26.1.Definition of Capacitance -- 26.2.Calculating Capacitance -- 26.3.Combinations of Capacitors -- 26.4.Energy Stored in a Charged Capacitor -- 26.5.Capacitors with Dielectrics -- 26.6.Electric Dipole in an Electric Field -- 26.7.An Atomic Description of Dielectrics -- 27.Current and Resistance -- 27.1.Electric Current -- 27.2.Resistance -- 27.3.A Model for Electrical Conduction -- 27.4.Resistance and Temperature -- 27.5.Superconductors -- 27.6.Electrical Power -- 28.Direct-Current Circuits -- 28.1.Electromotive Force -- 28.2.Resistors in Series and Parallel -- 28.3.Kirchhoff's Rules -- 28.4.RC Circuits -- 28.5.Household Wiring and Electrical Safety -- 29.Magnetic Fields -- 29.1.Analysis Model: Particle in a Field [Magnetic] -- 29.2.Motion of a Charged Particle in a Uniform Magnetic Field -- 29.3.Applications Involving Charged Particles Moving in a Magnetic Field -- 29.4.Magnetic Force Acting on a Current-Carrying Conductor -- 29.5.Torque on a Current Loop in a Uniform Magnetic Field -- 29.6.The Hall Effect -- 30.Sources of the Magnetic Field -- 30.1.The Biot-Savart Lam -- 30.2.The Magnetic Force Between Two Parallel Conductors -- 30.3.Ampere's Law -- 30.4.The Magnetic Field of a Solenoid -- 30.5.Gauss's Law in Magnetism -- 30.6.Magnetism in Matter -- 31.Faraday's Law -- 31.1.Faraday's Law of Induction -- 35.2.Motional emf -- 31.3.Lenz's Law -- 31.4.Induced emf and Electric Fields -- 31.5.Generators and Motors -- 31.6.Eddy Currents -- 32.Inductance -- 32.1.Self-Induction and Inductance -- 32.2.Fit Circuits -- 32.3.Energy in a Magnetic Field -- 32.4.Mutual Inductance -- 33.5.Oscillations in an LC Circuit -- 32.6.The RC Circuit -- 33.Alternating-Current Circuits -- 33.1.AC Sources -- 33.2.Resistors in an AC Circuit -- 33.3.Inductors in an AC Circuit -- 33.4.Capacitors in an AC Circuit -- 33.5.The RLC Series Circuit -- 33.6.Power in an AC Circuit -- 33.7.Resonance in a Series RLC Circuit -- 33.8.The Transformer and Power Transmission -- 33.9.Rectifiers and Filters -- 34.Electromagnetic Waves -- 34.1.Displacement Current and the General Form of Ampere's Law -- 34.2.Maxwell's Equations and Hertz's Discoveries -- 34.3.Plane Electromagnetic Waves -- 34.4.Energy Carried by Electromagnetic Waves -- 34.5.Momentum and Radiation Pressure --

ISBN: 9781133953999 (pbk.) :NT1360

Nat. Bib. No.: GBB2A9429bnbSubjects--Topical Terms:

672809
Physics

LC Class. No.: QC23 / .S46 2014

Dewey Class. No.: 530

Physics for scientists and engineers with modern physics /
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050 # 4 $a QC23 $b .S46 2014
082 0 4 $2 23 $a 530
100 1 $a Serway, Raymond A. $3 594807
245 1 0 $a Physics for scientists and engineers with modern physics / $c Raymond A. Serway, John W. Jewett, Jr. ; with contributions from Vahé Peroomian.
250 $a 9th ed., International ed.
260 # $a Boston, MA : $c 2014. $b Brooks/Cole, Cengage Learning,
300 $a xxxii, 1484, [95] p. : $b ill. (chiefly col.), ports. (some col.) ; $c 28 cm.
500 $a Includes index.
505 0 # $a Machine generated contents note: pt. 1 Mechanics -- 1.Physics and Measurement -- 1.1.Standards of Length, Mass, and Time -- 1.2.Matter and Model Building -- 1.3.Dimensional Analysis -- 1.4.Conversion of Units -- 1.5.Estimates and Order-of-Magnitude Calculations -- 1.6.Significant Figures -- 2.Motion in One Dimension -- 2.1.Position, Velocity, and Speed -- 2.2.Instantaneous Velocity and Speed -- 2.3.Analysis Model: Particle Under Constant Velocity -- 2.4.Acceleration -- 2.5.Motion Diagrams -- 2.6.Analysis Model: Particle Under Constant Acceleration -- 2.7.Freely Falling Objects -- 2.8.Kinematic Equations Derived from Calculus -- 3.Vectors -- 3.1.Coordinate Systems -- 3.2.Vector and Scalar Quantities -- 3.3.Some Properties of Vectors -- 3.4.Components of a Vector and Unit Vectors -- 4.Motion in Two Dimensions -- 4.1.The Position, Velocity, and Acceleration Vectors -- 4.2.Two-Dimensional Motion with Constant Acceleration -- 4.3.Projectile Motion -- 4.4.Analysis Model: Particle in Uniform Circular Motion -- 4.5.Tangential and Radial Acceleration -- 4.6.Relative Velocity and Relative Acceleration -- 5.The Laws of Motion -- 5.1.The Concept of Force -- 5.2.Newton's First Law and Inertial Frames -- 5.3.Mass -- 5.4.Newton's Second Law -- 5.5.The Gravitational Force and Weight -- 5.6.Newton's Third Law -- 5.7.Analysis Models Using Newton's Second Law -- 5.8.Forces of Friction -- 6.Circular Motion and Other Applications of Newton's Laws -- 6.1.Extending the Particle in Uniform Circular Motion Model -- 6.2.Nonuniform Circular Motion -- 6.3.Motion in Accelerated Frames -- 6.4.Motion in the Presence of Resistive Forces -- 7.Energy of a System -- 7.1.Systems and Environments -- 7.2.Work Done by a Constant Force -- 7.3.The Scalar Product of Two Vectors -- 7.4.Work Done by a Varying Force -- 7.5.Kinetic Energy and the Work-Kinetic Energy Theorem -- 7.6.Potential Energy of a System -- 7.7.Conservative and Nonconservative Forces -- 7.8.Relationship Between Conservative Forces and Potential Energy -- 7.9.Energy Diagrams and Equilibrium of a System -- 8.Conservation of Energy -- 8.1.Analysis Model: Nonisolated System (Energy) -- 8.2.Analysis Model: Isolated System (Energy) -- 8.3.Situations Involving Kinetic Friction -- 8.4.Changes in Mechanical Energy for Nonconservative Forces -- 8.5.Power -- 9.Linear Momentum and Collisions -- 9.1.Linear Momentum -- 9.2.Analysis Model: Isolated System (Momentum) -- 9.3.Analysis Model: Nonisolated System [Momentum] -- 9.4.Collisions in One Dimension -- 9.5.Collisions in Two Dimensions -- 9.6.The Center of Mass -- 9.7.Systems of Many Particles -- 9.8.Deformable Systems -- 9.9.Rocket Propulsion -- 10.Rotation of a Rigid Object About a Fixed Axis -- 10.1.Angular Position, Velocity, and Acceleration -- 10.2.Analysis Model: Rigid Object Under Constant Angular Acceleration -- 10.3.Angular and Translations! Quantities -- 10.4.Torque -- 10.5.Analysis Model: Rigid Object Under a Net Torque -- 10.6.Calculation of Moments of Inertia -- 10.7.Rotational Kinetic Energy -- 10.8.Energy Considerations in Rotational Motion -- 10.9.Rolling Motion of a Rigid Object -- 11.Angular Momentum -- 11.1.The Vector Product and Torque -- 11.2.Analysis Model: Nonisolated System (Angular Momentum) -- 11.3.Angular Momentum of a Rotating Rigid Object -- 11.4.Analysis Model: Isolated System (Angular Momentum) -- 11.5.The Motion of Gyroscopes and Tops -- 12.Static Equilibrium and Elasticity -- 12.1.Analysis Model: Rigid Object in Equilibrium -- 12.2.More on the Center of Gravity -- 12.3.Examples of Rigid Objects in Static Equilibrium -- 12.4.Elastic Properties of Solids -- 13.Universal Gravitation -- 13.1.Newton's Law of Universal Gravitation -- 13.2.Free-Fall Acceleration and the Gravitational Force -- 13.3.Analysis Model: Particle in a Field (Gravitational) -- 13.4.Kepler's Laws and the Motion of Planets -- 13.5.Gravitational Potential Energy -- 13.6.Energy Considerations in Planetary and Satellite Motion -- 14.Fluid Mechanics -- 14.1.Pressure -- 14.2.Variation of Pressure with Depth -- 14.3.Pressure Measurements -- 14.4.Buoyant Forces and Archimedes's Principle -- 14.5.Fluid Dynamics -- 14.6.Bernoulli's Equation -- 14.7.Other Applications of Fluid Dynamics -- pt. 2 Oscillations and Mechanical Waves -- 15.Oscillatory Motion -- 15.1.Motion of an Object Attached to a Spring -- 15.2.Analysis Model: Particle in Simple Harmonic Motion -- 15.3.Energy of the Simple Harmonic Oscillator -- 15.4.Comparing Simple Harmonic Motion with Uniform Circular Motion -- 15.5.The Pendulum -- 15.6.Damped Oscillations -- 15.7.Forced Oscillations -- 16.Wave Motion -- 16.1.Propagation of a Disturbance -- 16.2.Analysis Model: Traveling Wave -- 16.3.The Speed of Waves on Strings -- 16.4.Reflection and Transmission -- 16.5.Rate of Energy Transfer by Sinusoidal Waves on Strings -- 16.6.The Linear Wave Equation -- 17.Sound Waves -- 17.1.Pressure Variations in Sound Waves -- 17.2.Speed of Sound Waves -- 17.3.Intensity of Periodic Sound Waves -- 17.4.The Doppler Effect -- 18.Superposition and Standing Waves -- 18.1.Analysis Model: Waves in Interference -- 18.2.Standing Waves -- 18.3.Analysis Model: Waves Under Boundary Conditions -- 18.4.Resonance -- 18.5.Standing Waves in Air Columns -- 18.6.Standing Waves in Rods and Membranes -- 18.7.Beats: Interference in Time -- 18.8.Nonsinusoidal Wave Patterns -- pt. 3 Thermodynamics -- 19.Temperature -- 19.1.Temperature and the Zeroth Law of Thermodynamics -- 19.2.Thermometers and the Celsius Temperature Scale -- 19.3.The Constant-Volume Gas Thermometer and the Absolute Temperature Scale -- 19.4.Thermal Expansion of Solids and Liquids -- 19.5.Macroscopic Description of an Ideal Gas -- 20.The First Law of Thermodynamics -- 20.1.Heat and Internal Energy -- 20.2.Specific Heat and Calorimetry -- 20.3.Latent Heat -- 20.4.Work and Heat in Thermodynamic Processes -- 20.5.The First Law of Thermodynamics -- 20.6.Some Applications of the First Law of Thermodynamics -- 20.7.Energy Transfer Mechanisms in Thermal Processes -- 21.The Kinetic Theory of Gases -- 21.1.Molecular Mode! of an Ideal Gas -- 21.2.Molar Specific Heat of an Ideal Gas -- 21.3.The Equipartition of Energy -- 21.4.Adiabatic Processes for an Ideal Gas -- 21.5.Distribution of Molecular Speeds -- 22.Heat Engines, Entropy, and the Second Law of Thermodynamics -- 22.1.Heat Engines and the Second Law of Thermodynamics -- 22.2.Heat Pumps and Refrigerators -- 22.3.Reversible and Irreversible Processes -- 22.4.The Carnot Engine -- 22.5.Gasoline and Diesel Engines -- 22.6.Entropy -- 22.7.Changes in Entropy for Thermodynamic Systems -- 22.8.Entropy and the Second Law -- pt. 4 Electricity and Magnetism -- 23.Electric Fields -- 23.1.Properties of Electric Charges -- 23.2.Charging Objects by Induction -- 23.3.Coulomb's Law -- 23.4.Analysis Model: Particle in a Field [Electric] -- 23.5.Electric Field of a Continuous Charge Distribution -- 23.6.Electric Field Lines -- 23.7.Motion of a Charged Particle in a Uniform Electric Field -- 24.Gauss's Law -- 24.1.Electric Flux -- 24.2.Gauss's Law -- 24.3.Application of Gauss's Law to Various Charge Distributions -- 24.4.Conductors in Electrostatic Equilibrium -- 25.Electric Potential -- 25.1.Electric Potential and Potential Difference -- 25.2.Potential Difference in a Uniform Electric Field -- 25.3.Electric Potential and Potential Energy Due to Point Charges -- 25.4.Obtaining the Value of the Electric Field from the Electric Potential -- 25.5.Electric Potential Due to Continuous Charge Distributions -- 25.6.Electric Potential Due to a Charged Conductor -- 25.7.The Millikan Oil-Drop Experiment -- 25.8.Applications of Electrostatics -- 26.Capacitance and Dielectrics -- 26.1.Definition of Capacitance -- 26.2.Calculating Capacitance -- 26.3.Combinations of Capacitors -- 26.4.Energy Stored in a Charged Capacitor -- 26.5.Capacitors with Dielectrics -- 26.6.Electric Dipole in an Electric Field -- 26.7.An Atomic Description of Dielectrics -- 27.Current and Resistance -- 27.1.Electric Current -- 27.2.Resistance -- 27.3.A Model for Electrical Conduction -- 27.4.Resistance and Temperature -- 27.5.Superconductors -- 27.6.Electrical Power -- 28.Direct-Current Circuits -- 28.1.Electromotive Force -- 28.2.Resistors in Series and Parallel -- 28.3.Kirchhoff's Rules -- 28.4.RC Circuits -- 28.5.Household Wiring and Electrical Safety -- 29.Magnetic Fields -- 29.1.Analysis Model: Particle in a Field [Magnetic] -- 29.2.Motion of a Charged Particle in a Uniform Magnetic Field -- 29.3.Applications Involving Charged Particles Moving in a Magnetic Field -- 29.4.Magnetic Force Acting on a Current-Carrying Conductor -- 29.5.Torque on a Current Loop in a Uniform Magnetic Field -- 29.6.The Hall Effect -- 30.Sources of the Magnetic Field -- 30.1.The Biot-Savart Lam -- 30.2.The Magnetic Force Between Two Parallel Conductors -- 30.3.Ampere's Law -- 30.4.The Magnetic Field of a Solenoid -- 30.5.Gauss's Law in Magnetism -- 30.6.Magnetism in Matter -- 31.Faraday's Law -- 31.1.Faraday's Law of Induction -- 35.2.Motional emf -- 31.3.Lenz's Law -- 31.4.Induced emf and Electric Fields -- 31.5.Generators and Motors -- 31.6.Eddy Currents -- 32.Inductance -- 32.1.Self-Induction and Inductance -- 32.2.Fit Circuits -- 32.3.Energy in a Magnetic Field -- 32.4.Mutual Inductance -- 33.5.Oscillations in an LC Circuit -- 32.6.The RC Circuit -- 33.Alternating-Current Circuits -- 33.1.AC Sources -- 33.2.Resistors in an AC Circuit -- 33.3.Inductors in an AC Circuit -- 33.4.Capacitors in an AC Circuit -- 33.5.The RLC Series Circuit -- 33.6.Power in an AC Circuit -- 33.7.Resonance in a Series RLC Circuit -- 33.8.The Transformer and Power Transmission -- 33.9.Rectifiers and Filters -- 34.Electromagnetic Waves -- 34.1.Displacement Current and the General Form of Ampere's Law -- 34.2.Maxwell's Equations and Hertz's Discoveries -- 34.3.Plane Electromagnetic Waves -- 34.4.Energy Carried by Electromagnetic Waves -- 34.5.Momentum and Radiation Pressure --
505 0 # $a Note continued: 34.6.Production of Electromagnetic Waves by an Antenna -- 34.7.The Spectrum of Electromagnetic Waves -- pt. 5 Light and Optics -- 35.The Nature of Light and the Principles of Ray Optics -- 35.1.The Nature of Light -- 35.2.Measurements of the Speed of Light -- 35.3.The Ray Approximation in Ray Optics -- 35.4.Analysis Model: Wave Under Reflection -- 35.5.Analysis Model: Wave Under Refraction -- 35.6.Huygens's Principle -- 35.7.Dispersion -- 35.8.Total Internal Reflection -- 36.Image Formation -- 36.1.Images Formed by Flat Mirrors -- 36.2.Images Formed by Spherical Mirrors -- 36.3.Images Formed by Refraction -- 36.4.Images Formed by Thin Lenses -- 36.5.Lens Aberrations -- 36.6.The Camera -- 36.7.The Eye -- 36.8.The Simple Magnifier -- 36.9.The Compound Microscope -- 36.10.The Telescope -- 37.Wave Optics -- 37.1.Young's Double-Slit Experiment -- 37.2.Analysis Model: Waves in Interference -- 37.3.Intensity Distribution of the Double-Slit Interference Pattern -- 37.4.Change of Phase Due to Reflection -- 37.5.Interference in Thin Films -- 37.6.The Michelson Interferometer -- 38.Diffraction Patterns and Polarization -- 38.1.Introduction to Diffraction Patterns -- 38.2.Diffraction Patterns from Narrow Slits -- 38.3.Resolution of Single-Slit and Circular Apertures -- 38.4.The Diffraction Grating -- 38.5.Diffraction of X-Rays by Crystals -- 38.6.Polarization of Light Waves -- pt. 6 Modern Physics -- 39.Relativity -- 39.1.The Principle of Galilean Relativity -- 39.2.The Michelson-Morley Experiment -- 39.3.Einstein's Principle of Relativity -- 39.4.Consequences of the Special Theory of Relativity -- 39.5.The Lorentz Transformation Equations -- 39.6.The Lorentz Velocity Transformation Equations -- 39.7.Relativistic Linear Momentum -- 39.8.Relativistic Energy -- 39.9.The General Theory of Relativity -- 40.Introduction to Quantum Physics -- 40.1.Blackbody Radiation and Planck's Hypothesis -- 40.2.The Photoelectric Effect -- 40.3.The Compton Effect -- 40.4.The Nature of Electromagnetic Waves -- 40.5.The Wave Properties of Particles -- 40.6.A New Model: The Quantum Particle -- 40.7.The Double-Slit Experiment Revisited -- 40.8.The Uncertainty Principle -- 41.Quantum Mechanics -- 41.1.The Wave Function -- 41.2.Analysis Model: Quantum Particle Under Boundary Conditions -- 41.3.The Schrodinger Equation -- 41.4.A Particle in a Well of Finite Height -- 41.5.Tunneling Through a Potential Energy Barrier -- 41.6.Applications of Tunneling -- 41.7.The Simple Harmonic Oscillator -- 42.Atomic Physics -- 42.1.Atomic Spectra of Gases -- 42.2.Early Models of the Atom -- 42.3.Bohr's Model of the Hydrogen Atom -- 42.4.The Quantum Model of the Hydrogen Atom -- 42.5.The Wave Functions for Hydrogen -- 42.6.Physical Interpretation of the Quantum Numbers -- 42.7.The Exclusion Principle and the Periodic Table -- 42.8.More on Atomic Spectra: Visible and X-Ray -- 42.9.Spontaneous and Stimulated Transitions -- 42.10.Lasers -- 43.Molecules and Solids -- 43.1.Molecular Bonds -- 43.2.Energy States and Spectra of Molecules -- 43.3.Bonding in Solids -- 43.4.Free-Electron Theory of Metals -- 43.5.Band Theory of Solids -- 43.6.Electrical Conduction in Metals, Insulators, and Semiconductors -- 43.7.Semiconductor Devices -- 43.8.Superconductivity -- 44.Nuclear Structure -- 44.1.Some Properties of Nuclei -- 44.2.Nuclear Binding Energy -- 44.3.Nuclear Models -- 44.4.Radioactivity -- 44.5.The Decay Processes -- 44.6.Natural Radioactivity -- 44.7.Nuclear Reactions -- 44.8.Nuclear Magnetic Resonance and Magnetic Resonance Imaging -- 45.Applications of Nuclear Physics -- 45.1.Interactions Involving Neutrons -- 45.2.Nuclear Fission -- 45.3.Nuclear Reactors -- 45.4.Nuclear Fusion -- 45.5.Radiation Damage -- 45.6.Uses of Radiation -- 46.Particle Physics and Cosmology -- 46.1.The Fundamental Forces in Nature -- 46.2.Positrons and Other Antiparticles -- 46.3.Mesons and the Beginning of Particle Physics -- 46.4.Classification of Particles -- 46.5.Conservation Laws -- 46.6.Strange Particles and Strangeness -- 46.7.Finding Patterns in the Particles -- 46.8.Quarks -- 46.9.Multicolored Quarks -- 46.10.The Standard Model -- 46.11.The Cosmic Connection -- 46.12.Problems and Perspectives -- Appendices -- A.Tables -- A.1.Conversion Factors -- A.2.Symbols, Dimensions, and Units of Physical Quantities -- B.Mathematics Review -- B.1.Scientific Notation -- B.2.Algebra -- B.3.Geometry -- B.4.Trigonometry -- B.5.Series Expansions -- B.6.Differential Calculus -- B.7.Integral Calculus -- B.8.Propagation of Uncertainty -- C.Periodic Table of the Elements -- D.SI Units -- D.1.SI Units -- D.2.Some Derived SI Units.
650 # 0 $a Physics $3 672809
650 # 0 $a Physics $x Study and teaching (Higher) $v Textbooks. $3 977848
700 1 # $a Jewett, John W. $3 594806
700 1 # $a Peroomian, Vahé. $3 977847