Introductory Physics Volume Two

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186 Index B B Index † Energy Density of an Electric Field, 48 † Addition of Two Waves, 147 † Ampere’s Law - Time Varying, 120 † Ampere’s Law, 102 † Biot-Savart Law, 97 † Circular Trajectories, 84 † Conductor in Equilibrium: Charge, 43 † Conductor in Equilibrium: Field, 43 † Conductor in Equilibrium: Potential, 44 † Conductor in Equilibrium: Surface Field, 44 † Coulomb’s Law in Vector Form, 8 † Coulomb’s Law, 8 † Effective Capacitance, 65 † Effective Resistance, 64 † Electric Charge, 4 † Electric Field due to a Point Charge, 15 † Electric Field from the Electric Potential, 40 † Electric Potential of a Point Charge, 48 † Electrical Power, 61 † Electromagnetic Waves and Light, 139 † Energy Stored in a Capacitor, 47 † Faraday’s Law (alternate form), 117 † Faraday’s Law, 116 † Force Currents, 105 † Force on a Current in a Uniform Field, 82 † Gauss’s Law, 20 † Impedance: Capacitor, 125 † Impedance: Inductor, 124 † Interference of Two Sources, 150 † Kirchhoff’s Junction Rule, 61 † Kirchhoff’s Loop Rule, 62 † Law of reflection, 162 † Lenz’s Law, 119 † Magnetic Force on a Current, 82 † Magnetic Force, 81 † Magnification Equations, 169
B Index 187 † Ohm’s Law: Resistance, 60 † Ohm’s Law: Resistivity, 59 † Reflection Phase Shift, 154 † Short Wavelength Limit, 161 † Single Slit Diffraction, 155 † Snell’s Law, 163 † Superposition Theorem, 15 † Thin Lens Equations, 168 † Two Types of Charge, 4 † Wave due to a Sinusoidal Point Source, 142 † Wavelength in a Medium, 154 † Work by Magnetic Force, 84 alternating current, 122 capacitance, 46 conductivity, 59 conductor, 7 converging lens, 166 current density, 58 current, 58 cyclotron, 85 direct current, 122 displacement current, 120 Diverging Lens, 171 electric field, 10 electric field, 11 electric flux, 20 electric potential, 37 electromagnet, 97 electromagnetic, 139 electromotive force, 116 elements, 57 EMF, 116 equipotential, 41 Farad, 46 field lines, 14 focal length, 166 focal plane, 167 focal point, 166 focus, 166 frequency, 143 gain, 128 gradient, 40
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1 Introductory Physics Volume Two S
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1.1 Electric Charge 3 Demo 1 Electr
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1.1 Electric Charge 5 Then charge a
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- - - - - 1.2 Coulomb’s Law 7 How
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1.2 Coulomb’s Law 9 Example Consi
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1.3 Electric Field 11 + - Compute t
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1.3 Electric Field 13 points a well
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1.3 Electric Field 15 Look back now
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1.5 Continuous Charge Distributions
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1.6 Gauss’s Law 19 § 1.6 Gauss
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1.6 Gauss’s Law 21 Suppose that y
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1.7 More Examples 23 ⊲ Problem 1.
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1.7 More Examples 25 The net force
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1.7 More Examples 27 out the net fo
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1.7 More Examples 29 -4q +2q -q E -
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1.7 More Examples 31 The area vecto
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1.8 Homework 33 ⊲ Problem 1.14 Ri
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1.9 Summary 35 § 1.9 Summary Defin
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2.1 Electric Potential 37 2 Electri
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2.1 Electric Potential 39 Example S
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2.2 Equipotentials 41 ⊲ Problem 2
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2.3 Conductors in Equilibrium 43
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2.4 Capacitors 45 § 2.4 Capacitors
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2.5 Energy in an Electric Field 47
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2.7 More Examples 49 ⊲ Problem 2.
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2.7 More Examples 51 The resulting
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2.8 Homework 53 add up potential du
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2.8 Homework 55 ⊲ Problem 2.27 Ho
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3.2 Electric Current 57 3 Circuits
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3.3 Ohm’s Law 59 Some materials,
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3.5 Kirchhoff’s Rules 61 ⊲ Prob
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3.6 Resistors in Combination 63 par
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3.8 Capacitor Circuits 65 Theorem:
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3.9 More Examples 67 Note that the
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3.9 More Examples 69 This mean that
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3.9 More Examples 71 15Ω 5Ω 10Ω
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3.9 More Examples 73 First combine
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3.10 Homework 75 ⊲ Problem 3.16 B
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3.10 Homework 77 4 µF + - 2 µF +
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3.11 Summary 79 § 3.11 Summary Def
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4.2 Magnetic Force on a Current 81
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4.3 Trajectories Under Magnetic For
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4.4 Lorentz Force 85 with a charge
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4.5 Hall Effect 87 But this charge
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4.6 More Examples 89 -e F E v F B =
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4.6 More Examples 91 The force on t
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4.7 Homework 93 Imagine the closed
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4.7 Homework 95 circular orbits. Wr
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5.1 Sources of Magnetic Field 97 5
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5.1 Sources of Magnetic Field 99
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5.2 Ampere’s Law 101 and ⃗ dr s
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5.2 Ampere’s Law 103 This satisfi
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5.4 More Examples 105 distance r fr
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5.4 More Examples 107 up the integr
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5.4 More Examples 109 Use the Biot-
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5.5 Homework 111 The magnetic force
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5.5 Homework 113 3.00 A 1.00 A 1 mm
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6.2 Faraday’s Law 115 6 Time Vary
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6.2 Faraday’s Law 117 Definition:
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6.3 Maxwell’s Extension of Ampere
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6.4 Inductance 121 Example Suppose
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6.7 AC Circuit Elements 123 + V S-
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6.8 Phasor Diagrams 125 Theorem: Im
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6.8 Phasor Diagrams 127 What we wan
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6.9 Homework 129 ⊲ Problem 6.6 Sh
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6.9 Homework 131 (b) A small circul
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6.9 Homework 133 maximum current in
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Page 161 and 162: 8.2 Reflection 161 8 Geometric Opti
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Page 191 and 192: C Power Series Expansions 191 The F
Page 193: D Unit Prefixes 193 § D.3 Fundamen
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