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College Physics

College Physics is the best solution for today's college physics market. With a unique, new, approach to physics that builds a conceptual framework as motivation for the physical principles, consistent problem solving coverage, stunning art, extensive end-of-chapter material, and superior media support, Giambattista, Richardson, and Richardson delivers a product that addresses today's market needs with the best tools available.

Product Details

ISBN-13: 9780072537246
Publisher: McGraw-Hill Companies, The
Publication date: 01/28/2003
Pages: 583
Product dimensions: 8.60(w) x 10.90(h) x 0.80(d)

About the Author

Alan Giambattista teaches at the Cornell University, Ithaca, New York.
Betty McCarthy Richardson teaches at the Cornell University, Ithaca, New York.
1996 Nobel Prize in Physics

Table of Contents

Chapter 1: Introduction
1.1 Why study physics?
1.2 Talking physics
1.3 The use of mathematics
1.4 Scientific notation and significant figures
1.5 Units
1.6 Dimensional analysis
1.7 Problem-solving techniques
1.8 Approximation
1.9 Graphs

Chapter 2: Force
2.1 Force
2.2 Net force
2.3 Inertia and Equlibrium: Newton's first law of motion
2.4 Vector addition using components
2.5 Interaction pairs: Newton’s third law of motion
2.6 Gravitational forces
2.7 Contact forces
2.8 Tension
2.9 Fundamental forces

Chapter 3: Acceleration and Newton’s Second Law of Motion
3.1 Position and displacement
3.2 Velocity
3.3 Newton’s second law of motion
3.4 Applying Newton’s second law
3.5 Velocity is relative: reference frames

Chapter 4: Motion with a Changing Velocity
4.1 Motion along a line due to a constant net force
4.2 Visualizing motion along a line with constant acceleration
4.3 Free fall
4.4 Motion of projectiles
4.5 Apparent weight
4.6 Air resistance

Chapter 5: Circular Motion
5.1 Description of uniform circular motion
5.2 Centripetal acceleration
5.3 Banked curves
5.4 Circular orbits
5.5 Nonuniform circular motion
5.6 Angular acceleration
5.7 Artificial gravity

Chapter 6: Conservation of Energy
6.1 The law of conservation of energy
6.2 Work done by a constant force
6.3 Kinetic energy
6.4 Gravitational potential energy (1)
6.5 Gravitational potential energy (2)
6.6 Work done by variable forces: Hooke’s Law
6.7 Elastic potential energy
6.8 Power

Chapter 7: Linear Momentum
7.1 A vector conservation law
7.2 Momentum
7.3 The impulse-momentum theorem
7.4 Conservation of momentum
7.5 Center of mass
7.6 Motion of the center of mass
7.7 Collisions in one dimension
7.8 Collisions in two dimensions

Chapter 8: Torque and Angular Momentum
8.1 Rotational kinetic energy and rotational inertia
8.2 Torque
8.3 Work done by a torque
8.4 Equilibrium revisited
8.5 Equilibrium in the human body
8.6 Rotational form of Newton’s second law
8.7 The dynamics of rolling objects
8.8 Angular momentum
8.9 The vector nature of angular momentum

Chapter 9: Fluids
9.1 States of matter
9.2 Pressure
9.3 Pascal's principle
9.4 The effect of gravity on fluid pressure
9.5 Measuring pressure
9.6 Archimedes' principle
9.7 Fluid flow
9.8 Bernoulli's equation
9.9 Viscosity
9.10 Viscous drag
9.11 Surface tension

Chapter 10: Elasticity and Oscillations
10.1 Elastic deformations of solids
10.2 Hooke's law for tensile and compressive forces
10.3 Beyond Hooke's law
10.4 Shear and volume deformations
10.5 Simple harmonic motion
10.6 The period and frequency for SHM
10.7 Graphical analysis of SHM
10.8 The pendulum
10.9 Damped oscillations
10.10 Forced oscillations and resonance

Chapter 11: Waves
11.1 Waves and energy transport
11.2 Transverse and longitudinal waves
11.3 Speed of transverse waves on a string
11.4 Periodic waves
11.5 Mathematical description of a wave
11.6 Graphing waves
11.7 Principle of superposition
11.8 Reflection and refraction
11.9 Interference and diffraction
11.10 Standing waves

Chapter 12: Sound
12.1 Sound waves
12.2 The speed of sound waves
12.3 Amplitude and intensity of sound waves
12.4 Standing sound waves
12.5 The human ear
12.6 Timbre
12.7 Beats
12.8 The Doppler effect
12.9 Shock waves
12.10 Echolocation and medical imaging

Chapter 13: Temperature and the Ideal Gas
13.1 Temperature
13.2 Temperature scales
13.3 Thermal expansion of solids and liquids
13.4 Molecular picture of a gas
13.5 Absolute temperature and the ideal gas law
13.6 Kinetic theory of the ideal gas
13.7 Temperature and reaction rates
13.8 Collisions between gas molecules

Chapter 14: Heat
14.1 Internal energy
14.2 Heat
14.3 Heat capacity and specific heat
14.4 Specific heat of ideal gases
14.5 Phase transitions
14.6 Conduction
14.7 Convection
14.8 Radiation

Chapter 15: Thermodynamics
15.1 The first law of thermodynamics
15.2 Thermodynamic processes
15.3 Thermodynamic processes for an ideal gas
15.4 Reversible and irreversible processes
15.5 Heat engines
15.6 Refrigerators and heat pumps
15.7 Reversible engines and heat pumps
15.8 Details of the Carnot cycle
15.9 Entropy
15.10 Statistical interpretation of entropy
15.11 The third law of thermodynamics

Chapter 16: Electric Forces and Fields
16.1 Electric charge
16.2 Conductors and insulators
16.3 Coulomb’s law
16.4 The electric field
16.5 Motion of a point charge in a uniform electric field
16.6 Conductors in electrostatic equilibrium
16.7 Gauss's law for electric fields

Chapter 17: Electric Potential
17.1 Electric potential energy
17.2 Electric potential
17.3 The relationship between electric field and potential
17.4 Conservation of energy for moving charges
17.5 Capacitors
17.6 Dielectrics
17.7 Energy stored in a capacitor

Chapter 18: Electric Current and Circuits
18.1 Electric current
18.2 Emf and circuits
18.3 Microscopic view of current in a metal
18.4 Resistance and resistivity
18.5 Kirchoff’s rules
18.6 Series and parallel circuits
18.7 Circuit analysis using Kirchoff’s rules
18.8 Power and energy in circuits
18.9 Measuring currents and voltages
18.10 RC circuits
18.11 Electrical safety

Chapter 19: Magnetic Forces and Fields
19.1 Magnetic fields
19.2 Magnetic force on a point charge
19.3 Charged particle moving perpendicular to a uniform magnetic field
19.4 Motion of a charged particle in a uniform magnetic field: general
19.5 A charged particle in crossed E and B fields
19.6 Magnetic force on a current-carrying wire
19.7 Torque on a current loop
19.8 Magnetic field due to an electric current
19.9 Ampère’s law
19.10 Magnetic materials

Chapter 20: Electromagnetic Induction
20.1 Motional Emf
20.2 Electric generators
20.3 Faraday's law
20.4 Lenz's law
20.5 Back Emf in a motor
20.6 Transformers
20.7 Eddy currents
20.8 Induced electric fields
20.9 Mutual and self-inductance
20.10 LR circuits

Chapter 21: Alternating Current
21.1 Sinusoidal currents and voltages; resistors in AC circuits
21.2 Electricity in the home
21.3 Capacitors in AC circuits
21.4 Inductors in AC circuits
21.5 RLC series circuit
21.6 Resonance in an RLC circuit
21.7 Converting AC to DC; filters

Chapter 22: Electromagnetic Waves
22.1 Accelerating charges produce electromagnetic waves
22.2 Maxwell’s equations
22.3 Antennas
22.4 The electromagnetic spectrum
22.5 Speed of EM waves in vacuum and in matter
22.6 Characteristics of electromagnetic waves in vacuum
22.7 Energy transport by EM waves
22.8 Polarization
22.9 The Doppler effect for EM waves

Chapter 23: Reflection and Refraction of Light
23.1 Wavefronts, rays, and Huygens’ principle
23.2 The reflection of light
23.3 The refraction of light: Snell’s law
23.4 Total internal reflection
23.5 Brewster’s angle
23.6 The formation of images through reflection or refraction
23.7 Plane mirrors
23.8 Spherical mirrors
23.9 Thin lenses

Chapter 24: Optical Instruments
24.1 Lenses in combination
24.2 Cameras
24.3 The eye
24.4 The simple magnifier
24.5 Compound microscopes
24.6 Telescopes
24.7 Aberrations of lenses and mirrors

Chapter 25: Interference and Diffraction
25.1 Constructive and destructive interference
25.2 The Michelson interferometer
25.3 Thin films
25.4 Young’s double slit experiment
25.5 Gratings
25.6 Diffraction and Huygens’ principle
25.7 Diffraction by a single slit
25.8 Diffraction and the resolution of optical instruments
25.9 X-ray diffraction
25.10 Holography

Chapter 26: Relativity
26.1 Postulates of relativity
26.2 Simultaneity and ideal observers
26.3 Time dilation
26.4 Length contraction
26.5 Velocities in different reference frames
26.6 Relativistic momentum
26.7 Mass and energy
26.8 Relativistic kinetic energy

Chapter 27: Early Quantum Physics and the Photon
27.1 Quantization
27.2 Blackbody radiation
27.3 The photoelectric effect
27.4 X-ray production
27.5 Compton scattering
27.6 Spectroscopy and early models of the atom
27.7 The Bohr model of the hydrogen atom; atomic energy levels
27.8 Pair annihilation and pair production

Chapter 28: Quantum Physics
28.1 The wave-particle duality
28.2 Matter waves
28.3 Electron microscopes
28.4 The uncertainty principle
28.5 Wave functions for a confined particle
28.6 The hydrogen atom: wave functions and quantum numbers
28.7 The exclusion principle: electron configurations for atoms other than hydrogen
28.8 Electron energy levels in a solid
28.9 Lasers
28.10 Tunneling

Chapter 29: Nuclear Physics
29.1 Nuclear structure
29.2 Binding energy
29.3 Radioactivity
29.4 Radioactive decay rates and half-lives
29.5 Biological effects of radiation
29.6 Induced nuclear reactions
29.7 Fission
29.8 Fusion

Chapter 30: Particle Physics
30.1 Fundamental particles
30.2 Fundamental interactions
30.3 Unification
30.4 “Who ordered that?”
30.5 Twenty-first-century particle physics

Appendix A: Mathematics Review
A.1 Algebra
A.2 Solving equations
A.3 Exponents and logarithms
A.4 Proportions and ratios
A.5 Geometry
A.6 Trigonometry
A.7 Approximations
A.8 Vectors

Appendix B: Table of Selected Isotopes

Answers to Selected Questions and Problems

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