Correlations

Physics, 1st Edition ©2002

James S. Walker

Correlated with AP* Physics, May 2002, May 2003

ST = Student textbook pages

1. Newtonian Mechanics
   1. Kinematics (including vectors, vector algebra, components of vectors, coordinate systems, displacement, velocity, and acceleration)
      1. Motion in one direction
         ST: 16–17, 77, 324
      2. Motion in two directions, including projectile motion
         ST: 77–81, 81–82, 87, 92, 99, 100–102, 948
   2. Newton's Laws of Motion (including friction and centripetal force)
      1. Static equilibrium (first law)
         ST: 104–107
      2. Dynamics of a single particle (second law)
         ST: 107–115, 132–133, 154, 236, 242, 307–308, 325
      3. Systems of two or more bodies (third law)
         ST: 115–118
   3. Work, energy, power
      1. Work and work-energy theorem
         ST: 174–181, 185–189, 194, 202–208, 228–229, 481, 720
      2. Conservative forces and potential energy
         ST: 202–204, 395–396, 399
      3. Conservation of energy
         ST: 289–294, 300–301, 649–651, 652, 514–516
      4. Power
         ST: 190–192, 791, 796, 798
   4. Systems of particles, linear momentum
      1. Center of mass
         ST: 232, 256–261
      2. Impulse and momentum
         ST: 232–233, 236–240, 266, 845–846, 959–961, 988–990, 959–961, 1007
      3. Conservation of linear momentum, collisions
         ST: 233–235
   5. Circular motion and rotation
      1. Uniform circular motion
         ST: 385–390, 411–412
      2. Angular momentum and its conservation
         1. Point particles
            ST: 17, 323
         2. Extended bodies, including rotational inertia
            ST: 285–289, 293, 300
      3. Torque and rotational statics
         ST: 303, 304–307, 307–310, 320–322, 327, 356
      4. Rotational kinematics and dynamics
         ST: 276–279, 298
   6. Oscillations and gravitation
      1. Simple harmonic motion (dynamics and energy relationships)
         ST: 383–385, 388, 395–398
      2. Mass on a spring
         ST: 166–167, 207, 215–216
      3. Pendulum and other oscillations
         ST: 381, 385, 398–404, 406, 412–413
      4. Newton's laws of gravity
         ST: 615
      5. Orbits of planets and satellites
         1. Circular
            ST: 345–346
         2. General
            ST: 345–346, 354–361, 377
   
   
2. Fluid Mechanics and Thermal Physics
   1. Fluid Mechanics
      1. Hydrostatic pressure
         ST: 464–465, 481–482
      2. Buoyancy
         ST: 460, 471–472, 472–478, 494–495
      3. Fluid flow continuity
         ST: 479–480, 495
      4. Bernoulli's equation
         ST: 482–483, 484–487, 495–496
   2. Temperature and heat
      1. Mechanical equivalent of heat
         ST: 510–511, 512, 529–530
      2. Specific and latent heat (including calorimetry)
         ST: 512–516, 555–559
      3. Heat transfer and thermal expansion
         ST: 499, 504–510, 529
   3. Kinetic theory and thermodynamics
      1. Ideal gases
         1. Kinetic model
            ST: 538–545
         2. Ideal gas law
            ST: 534
      2. Laws of thermodynamics
         1. First law (including processes on pV diagrams)
            ST: 570–572, 603–604
         2. Second law (including heat engines)
            ST: 585, 595, 598
   
   
3. Electricity and Magnetism
   1. Electrostatics
      1. Charge, field, and potential
         ST: 720–725
      2. Coulomb's law and field and potential of point charges
         ST: 614–621, 641–642, 1016, 1053
      3. Fields and potentials of other charge distributions
         1. Planar
            ST: 652–656
         2. Spherical symmetry
            ST: 620–621, 635–636
         3. Cylindrical symmetry
            ST: 636
      4. Gauss's law
         ST: 634–637
   2. Conductors, capacitors, dielectrics
      1. Electrostatics with conductors
         ST: 631–632
      2. Capacitors
         1. Parallel plate
            ST: 629–630
         2. Spherical and cylindrical
            ST: 620–621
      3. Dielectrics
         ST: 663–666, 674–675
   3. Electric circuits
      1. Current, resistance, power
         ST: 768, 722
      2. Steady-state direct current circuits with batteries and resistors
         ST: 681–684
      3. Capacitors in circuits
         1. Steady state
            ST: 645–646, 660–666
         2. Transients in RC circuits
            ST: 699–703
   4. Magnetostatics
      1. Forces on moving charges in magnetic fields
         ST: 719–721, 817–818
      2. Forces on current-carrying wires in magnetic fields
         ST: 729–733
      3. Fields of long current-carrying wires
         ST: 729–733
      4. Biot-Savart and Ampere's law
         ST: 729–733, 735
   5. Electromagnetism
      1. Electromagnetic induction (including Faraday's law and Lenz's law)
         ST: 752–755, 755–759, 778
      2. Inductance (including LR and LC circuits)
         ST: 765–767, 779
      3. Maxwell's equations
         ST: 1012
   
   
4. Waves and Optics
   1. Wave motion (including sound)
      1. Properties of traveling waves
         ST: 415–419
      2. Properties of standing waves
         ST: 442–449
      3. Doppler effect
         ST: 432–438, 457, 822
      4. Superposition
         ST: 438–439
   2. Physical optics
      1. Interference and diffraction
         ST: 914–916, 921, 923–926, 935, 993, 994
      2. Dispersion of light and the electromagnetic spectrum
         ST: 920–927, 993, 996
   3. Geometric optics
      1. Reflection and refraction
         ST: 838–840, 848–850
      2. Mirrors
         ST: 856, 859–863, 883
      3. Lenses
         ST: 870, 906–907, 926
   
   
5. Atomic and Nuclear Physics
   1. Atomic physics and quantum effects
      1. Photons and the photoelectric effect
         ST: 978, 983–988
      2. Atomic energy particles
         ST: 1031–1033, 1033–1041
      3. Wave-particle duality
         ST: 1033–1036, 1040–1041
   2. Nuclear physics
      1. Nuclear reactions (including conservation of mass number and charge)
         ST: 1049–1054
      2. Mass-energy equivalence
         ST: 1077–1080, 1080–1081