Chapter 2: Kinematics: Motion in One DimensionSection 2.1:
What is motion?
Section 2.2:
A conceptual description of motion
Section 2.3:
Operations with vectors
Section 2.4:
Quantities for describing motion
Section 2.5:
Representing motion with data tables and graphs
Section 2.6:
Constant velocity linear motion
Section 2.7:
Motion at constant acceleration
Section 2.8:
Displacement of an object moving at constant acceleration
Section 2.9:
Skills for analyzing situations involving motion
Page 43:
Questions
Page 45:
Problems
Chapter 3: Newtonian MechanicsSection 3.1:
Describing and representing interactions
Section 3.2:
Adding and measuring forces
Section 3.3:
Conceptual relationship between force and motion
Section 3.4:
Inertial reference frames and Newton's first law
Section 3.5:
Newton's second law
Section 3.6:
Gravitational force law
Section 3.7:
Skills for applying Newton's second law for one-dimensional processes
Section 3.8:
Forces come in pairs: Newton's third law
Section 3.9:
Seat belts and air bags
Page 78:
Questions
Page 80:
Problems
Chapter 4: Applying Newton's LawsSection 4.1:
Vectors in two dimensions and force components
Section 4.2:
Newton's second law in component form
Section 4.3:
Friction
Section 4.4:
Skills for analyzing processes involving forces in two dimensions
Section 4.5:
Projectile motion
Section 4.6:
Starting and stopping a car
Page 110:
Questions
Page 111:
Problems
Chapter 5: Circular MotionSection 5.1:
Qualitative dynamics of circular motion
Section 5.2:
Analyzing velocity change for circular motion
Section 5.3:
Radial acceleration and period
Section 5.4:
Skills for analyzing processes involving circular motion
Section 5.5:
The law of universal gravitation
Page 140:
Questions
Page 141:
Problems
Chapter 6: Impulse and Linear MomentumSection 6.1:
Mass accounting
Section 6.2:
Linear momentum
Section 6.3:
Impulse and momentum
Section 6.4:
The generalized impulse-momentum principle
Section 6.5:
Skills for analyzing problems using impulse and momentum
Section 6.6:
Jet propulsion
Section 6.7:
Collisions in two dimensions
Page 169:
Questions
Page 170:
Problems
Chapter 7: Work and EnergySection 7.1:
Work and energy
Section 7.2:
Energy is a conserved quantity
Section 7.3:
Quantifying gravitational potential and kinetic energies
Section 7.4:
Quantifying elastic potential energy
Section 7.5:
Friction and energy conversion
Section 7.6:
Skills for analyzing processes using the work-energy principle
Section 7.7:
Collisions
Section 7.8:
Power
Section 7.9:
Improving our model of gravitational potential energy
Page 209:
Questions
Page 210:
Problems
Chapter 8: Extended Bodies at RestSection 8.1:
Extended and rigid bodies
Section 8.2:
Torque: a new physical quantity
Section 8.3:
Conditions of equilibrium
Section 8.4:
Center of mass
Section 8.5:
Skills for analyzing situations using equilibrium conditions
Section 8.6:
Stability of equilibrium
Page 243:
Questions
Page 244:
Problems
Chapter 9: Rotational MotionSection 9.1:
Rotational kinematics
Section 9.2:
Physical quantities affecting rotational acceleration
Section 9.3:
Newton's second law for rotational motion
Section 9.4:
Rotational momentum
Section 9.5:
Rotational kinetic energy
Section 9.6:
Tides and Earth's day
Page 277:
Questions
Page 278:
Problems
Chapter 10: Vibrational MotionSection 10.1:
Observations of vibrational motion
Section 10.2:
Kinematics of vibrational motion
Section 10.3:
Dynamics of simple harmonic motion
Section 10.4:
Energy of vibrational systems
Section 10.5:
The simple pendulum
Section 10.6:
Skills for analyzing processes involving vibrational motion
Section 10.7:
Including friction in vibrational motion
Section 10.8:
Vibrational motion with an external driving force
Page 309:
Questions
Page 310:
Problems
Chapter 11: Mechanical WavesSection 11.1:
Observations: pulses and wave motion
Section 11.2:
Mathematical descriptions of a wave
Section 11.3:
Dynamics of wave motion: speed and the medium
Section 11.4:
Energy, power, and intensity of waves
Section 11.5:
Reflection and impedance
Section 11.6:
Superposition principle and skills for analyzing wave processes
Section 11.7:
Sound
Section 11.8:
Standing waves on strings
Section 11.9:
Standing waves in air columns
Section 11.10:
The Doppler effect
Page 346:
Questions
Page 347:
Problems
Section 12.1:
Structure of matter
Section 12.2:
Pressure, density, and the mass of particles
Section 12.3:
Quantitative analysis of an ideal gas
Section 12.4:
Temperature
Section 12.5:
Testing the ideal gas law
Section 12.6:
Speed distribution of particles
Section 12.7:
Skills for analyzing processes using the ideal gas law
Section 12.8:
Thermal energy, the Sun, and diffusion
Page 380:
Questions
Page 381:
Problems
Section 13.1:
Density
Section 13.2:
Pressure inside a fluid
Section 13.3:
Pressure variation with depth
Section 13.4:
Measuring atmospheric pressure
Section 13.5:
Bouyant force
Section 13.6:
Skills for analyzing static fluid problems
Section 13.7:
Ships, baloons, climbing, and diving
Page 408:
Questions
Page 409:
Problems
Chapter 14: Fluids in MotionSection 14.1:
Fluids moving across surfaces - qualitative analysis
Section 14.2:
Flow rate and fluid speed
Section 14.3:
Types of fluid flow
Section 14.4:
Bernoulli's equation
Section 14.5:
Skills for analyzing processes using Bernoulli's equation
Section 14.6:
Viscous fluid flow
Section 14.7:
Drag forcePage 435:
Questions
Page 436:
Problems
Chapter 15: First Law of ThermodynamicsSection 15.1:
Internal energy and work in gas processes
Section 15.2:
Two ways to change the energy of a system
Section 15.3:
First law of thermodynamics
Section 15.4:
Applying the first law of thermodynamics to gas processes
Section 15.5:
Specific heat
Section 15.6:
Phase change
Section 15.7:
Heating mechanisms
Page 471:
Questions
Page 472:
Problems
Chapter 16: Second Law of ThermodynamicsSection 16.1:
Irreversible processes
Section 16.2:
Entropy: the microscopic approach
Section 16.3:
Entropy: the macroscopic approach
Section 16.4:
Quantitative analysis of thermodynamic engines and pumps
Page 496:
Questions
Page 497:
Problems
Chapter 17: Electric Charge, Force, and EnergySection 17.1:
Electrostatic interactions
Section 17.2:
Explanations for electrostatic interactions
Section 17.3:
Conductors and insulators (dielectrics)
Section 17.4:
Coulomb's force law
Section 17.5:
Electric potential energy
Section 17.6:
Skills for analyzing processes involving electric charges
Section 17.7:
Charge separation and photocopying
Page 529:
Questions
Page 530:
Problems
Chapter 18: The Electric FieldSection 18.1:
A model of the mechanism for electrostatic interactions
Section 18.2:
Skills for analyzing processes involving E fields
Section 18.3:
The V field: electric potential
Section 18.4:
Relating the E field and the V field
Section 18.5:
Conductors in electric fields
Section 18.6:
Dielectric materials in an electric field
Section 18.7:
Capacitors
Section 18.8:
Electrocardiography
Page 566:
Questions
Page 567:
Problems
Section 19.1:
Electric current
Section 19.2:
Batteries and emf
Section 19.3:
Making and representing simple circuits
Section 19.4:
Ohm's law
Section 19.5:
Qualitative analysis of circuits
Section 19.6:
Joule's law
Section 19.7:
Kirchhoff's rules
Section 19.8:
Resistor and capacitor circuits
Section 19.9:
Skills for solving circuit problems
Section 19.10:
Properties of resistors
Page 609:
Questions
Page 610:
Problems
Section 20.1:
Magnetic interactions
Section 20.2:
Magnetic field
Section 20.3:
Magnetic force on a current-carrying wire
Section 20.4:
Magnetic force exerted on a single moving charged particle
Section 20.5:
Magnetic fields produced by electric currents
Section 20.6:
Skills for analyzing magnetic processes
Section 20.7:
Magnetic properties of materials
Page 643:
Questions
Page 644:
Problems
Chapter 21: Electromagnetic InductionSection 21.1:
Inducing an electric current
Section 21.2:
Magnetic flux
Section 21.3:
Direction on the induced current
Section 21.4:
Faraday's law of electromagnetic induction
Section 21.5:
Skills for analyzing processes involving electromagnetic induction
Section 21.6:
AC circuits
Section 21.7:
Transformers
Section 21.8:
Mechanisms explaining electromagnetic induction
Page 679:
Questions
Page 680:
Problems
Chapter 22: Reflection and RefractionSection 22.1:
Light sources, light propagation, and shadows
Section 22.2:
Reflection of light
Section 22.3:
Refraction of light
Section 22.4:
Total internal reflection
Section 22.5:
Skills for analyzing reflective and refractive processes
Section 22.6:
Fiber optics, prisms, mirages, and the color of the sky
Section 22.7:
Explanation of light phenomena: two models of light
Page 707:
Questions
Page 708:
Problems
Chapter 23: Mirrors and LensesSection 23.1:
Plane mirrors
Section 23.2:
Qualitative analysis of curved mirrors
Section 23.3:
The mirror equation
Section 23.4:
Qualitative analysis of lensesSection 23.5:
Thin lens equation and quantitative analysis of lenses
Section 23.6:
Skills for analyzing processes involving mirrors and lenses
Section 23.7:
Single-lens optical systems
Section 23.8:
Angular magnification and magnifying glasses
Section 23.9:
Telescopes and microscopes
Page 745:
Questions
Page 746:
Problems
Section 24.1:
Young's double-slit experiment
Section 24.2:
Refractive index, light speed, and wave coherence
Section 24.3:
Gratings: an application of interference
Section 24.4:
Thin-film interferenceSection 24.5:
Diffraction of lightSection 24.6:
Resolving powerSection 24.7:
Skills for applying the wave model of light
Page 778:
Questions
Page 779:
Problems
Chapter 25: Electromagnetic WavesSection 25.1:
Polarization of waves
Section 25.2:
Discovery of electromagnetic waves
Section 25.3:
Applications of electromagnetic waves
Section 25.4:
Frequency, wavelength, and the electromagnetic spectrum
Section 25.5:
Mathematical description of EM waves and EM wave energy
Section 25.6:
Polarization and light reflection
Page 809:
Problems
Page 809:
Questions
Chapter 26: Special RelativitySection 26.1:
Ether or no ether?
Section 26.2:
Postulates of special relativity
Section 26.3:
Simultaneity
Section 26.4:
Time dilation
Section 26.5:
Length contraction
Section 26.6:
Spacetime diagrams
Section 26.7:
Velocity transformations
Section 26.8:
Relativistic momentum
Section 26.9:
Relativistic energy
Section 26.10:
Doppler effect for EM waves
Section 26.11:
General relativity
Section 26.12:
Global Positioning System (GPS)
Page 843:
Questions
Page 844:
Problems
Chapter 27: Quantum OpticsSection 27.1:
Black body radiation
Section 27.2:
Photoelectric effect
Section 27.3:
Quantum model explanation of the photoelectric effect
Section 27.4:
Photons
Section 27.5:
X-rays
Section 27.6:
Photocells, solar cells, and LEDs
Page 876:
Questions
Page 876:
Problems
Chapter 28: Atomic PhysicsSection 28.1:
Early atomic models
Section 28.2:
Bohr's model of the atom: quantized orbits
Section 28.3:
Spectral analysis
Section 28.4:
Lasers
Section 28.5:
Quantum numbers and Pauli's exclusion principle
Section 28.6:
Particles are not just particles
Section 28.7:
Multi-electron atoms and the periodic table
Section 28.8:
The uncertainty principle
Page 916:
Questions
Page 917:
Problems
Chapter 29: Nuclear PhysicsSection 29.1:
Radioactivity and an early nuclear model
Section 29.2:
A new particle and a new nuclear model
Section 29.3:
Nuclear force and binding energy
Section 29.4:
Nuclear reactions
Section 29.5:
Nuclear sources of energy
Section 29.6:
Mechanisms of radioactive decay
Section 29.7:
Half-life, decay rate, and exponential decay
Section 29.8:
Radioactive dating
Section 29.9:
Ionizing radiation and its measurement
Page 953:
Problems
Page 953:
Questions
Chapter 30: Particle PhysicsSection 30.1:
Antiparticles
Section 30.2:
Fundamental interactions
Section 30.3:
Elementary particles and the Standard Model
Section 30.4:
Cosmology
Section 30.5:
Dark matter and dark energy
Page 979:
Questions
Page 980:
Problems
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