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Version Date: January 9, 2013
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Links in Text 8.02x
Table of Contents
(LIVE LINKS)
1 Movies......................................................................................................................... 3 1.1 Figure 1.1.1 1-2 ................................................................................................ 3 1.2 Figure 1.4.1(a) 1-10 ......................................................................................... 3 1.3 Figure 1.4.1(b) 1-10 ......................................................................................... 3 1.4 Figure 1.4.2 1-10 .............................................................................................. 3 1.5 Figure 1.4.3(a) 1-11 ......................................................................................... 4 1.6 Figure 1.4.3(b) 1-11 .......................................................................................... 4 1.7 Figure 1.4.4 1-11 .............................................................................................. 4 1.8 Figure 1.4.5(a) 1-12 ......................................................................................... 4 1.9 Figure 1.4.5(b) 1-12 ......................................................................................... 4 1.10 Figure 1.4.6(a) 1-13 ......................................................................................... 5 1.11 Figure 1.4.6(b) 1-13 ......................................................................................... 5 1.12 Figure 1.4.7 1-13 .............................................................................................. 5 1.13 Figure 1.4.8 1-14 ................................................................................................ 5 1.14 Figure 1.6.2 ......................................................................................................... 6 1.15 Figure 1.7.4 ......................................................................................................... 6 1.16 Figure 1.8.5: ........................................................................................................ 7 1.17 Figure 2.4.2 ......................................................................................................... 7 1.18 Figure 2.11.1 ....................................................................................................... 8 1.19 Figure 2.11.2 ....................................................................................................... 8 1.20 Figure 2.11.4 ....................................................................................................... 8 1.21 Figure 2.11.5 ....................................................................................................... 9 1.22 Figure 2.11.6 ....................................................................................................... 9 1.23 Figure 5.5.2 ....................................................................................................... 10 1.24 Figure 5.5.3 ....................................................................................................... 10 1.25 Figure 5.7.1 ....................................................................................................... 11 1.26 Figure 5.7.2 ....................................................................................................... 11 1.27 Figure 8.6.1 ....................................................................................................... 11 1.28 Figure 8.6.2 ....................................................................................................... 12 1.29 Figure 8.6.3 ....................................................................................................... 12 1.30 Figure 8.6.4 ....................................................................................................... 13 1.31 Figure 8.6.5 ....................................................................................................... 13 1.32 Figure 9.1.7 ....................................................................................................... 13 1.33 Figure 9.1.8 ....................................................................................................... 14 1.34 Figure 9.2.1 ....................................................................................................... 14 1.35 Figure 9.2.2 ....................................................................................................... 15 1.36 Figure 9.9.3 ....................................................................................................... 15 1.37 Figure 9.9.6 ....................................................................................................... 16 1.38 Figure 9.9.7 ....................................................................................................... 16 1.39 Figure 9.9.8 ....................................................................................................... 17 Version Date: January 9, 2013
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1.40 Figure 9.9.9 ....................................................................................................... 17 1.41 Figure 10.1.2 ..................................................................................................... 17 1.42 Figure 10.1.3 ..................................................................................................... 18 1.43 Figure 10.4.5 ..................................................................................................... 18 1.44 Figure 11.3.1 ..................................................................................................... 18 1.45 Figure 13.8.5 ..................................................................................................... 19 1.46 Figure 13.8.6 ..................................................................................................... 19 1.47 Figure 13.8.7 ..................................................................................................... 19 2 Simulations ............................................................................................................... 21 2.1 Figure 1.8.1 ....................................................................................................... 21 2.2 Figure 1.8.2 ....................................................................................................... 21 2.3 Figure 1.8.4: ...................................................................................................... 21 2.4 Figure 3.10.1 ..................................................................................................... 22 2.5 Figure 8.13.1 ..................................................................................................... 22 2.6 Figure 9.14.1 ..................................................................................................... 22 2.7 Figure 9.14.1 ..................................................................................................... 23 2.8 Figure 13.15.1 ................................................................................................... 23 Version Date: January 9, 2013
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1
1.1
Figure 1.1.1
1-2
http://youtu.be/rU7QOukFjTo
1.2
Figure 1.4.1(a)
1-10
http://youtu.be/zJS-6JrZMtM
1.3
Figure 1.4.1(b)
1-10
http://youtu.be/PKLcAH9-jKs
1.4
Figure 1.4.2
1-10
http://youtu.be/DyWgfvzJWxQ
Movies
Version Date: January 9, 2013
1.5
Figure 1.4.3(a)
1-11
http://youtu.be/eM1-NxX5dqA
1.6
Figure 1.4.3(b) 1-11
http://youtu.be/oRs-RkA-zIA
1.7
Figure 1.4.4
1-11
http://youtu.be/ZNPIL5tH-pc
1.8
Figure 1.4.5(a)
1-12
http://youtu.be/ErA2xChpNaw
1.9
Figure 1.4.5(b) 1-12
http://youtu.be/4Y0K7liK4-0
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Version Date: January 9, 2013
1.10 Figure 1.4.6(a)
1-13
http://youtu.be/66U6kUjwhH8
1.11 Figure 1.4.6(b)
1-13
http://youtu.be/iC66c88Y3zo
1.12 Figure 1.4.7
1-13
http://youtu.be/08pwP4RRMhk
1.13 Figure 1.4.8 1-14
http://youtu.be/dad9C7L3ynw
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1.14 Figure 1.6.2
The electric fields of (a) a moving positive charge, (b) a moving negative charge when
the speed of the charge is small compared to the speed of light.
(a) http://youtu.be/gWa0s3V9DeM
(b) http://youtu.be/Am5EYvNgjE
1.15 Figure 1.7.4
The magnetic field of (a) a moving positive charge and of (b) a moving negative charge
when the speed of the charge is small compared to c.
(a) http://youtu.be/JmqX1GrMYnU
(b) http://youtu.be/Apde4g619RA
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1.16 Figure 1.8.5:
One frame of a movie showing the electric field lines of a positive charge moving upward
in a downward constant field.! The
! motion of the field lines and texture patterns in this
movie are in the direction of E ! B .
http://youtu.be/WSMsse6lPHM
1.17 Figure 2.4.2
The electric fields of (a) a moving positive charge, (b) a moving negative charge, when
the speed of the charge is small compared to the speed of light.
(a) http://youtu.be/gWa0s3V9DeM
(b) http://youtu.be/Am5EYvNgjE
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1.18 Figure 2.11.1
(a) Two charges of the same sign that repel one another because of the “stresses”
transmitted by electric fields. We use both the “grass seeds” representation and the ”field
lines” representation of the electric field of the two charges. (b) Two charges of opposite
sign that attract one another because of the stresses transmitted by electric fields.
(a) http://youtu.be/mXRU8a188q0
(b )http://youtu.be/koYPUVr2vyg
1.19 Figure 2.11.2
A positive charge moving in a constant electric field which points downward. (a) The
total field configuration when the charge is still out of sight on the negative z-axis. (b)
The total field configuration when the charge comes to rest at the origin, before it moves
back down the negative z-axis.
(a) http://youtu.be/WSMsse6lPHM
1.20 Figure 2.11.4
(b) http://youtu.be/WSMsse6lPHM
Two frames of a movie of the electric field around a positive charge fixed at rest in a
time-changing electric field that points downward. The orange vector is the electric field
and the lighter-colered vector is the force on the point charge.
(a) http://youtu.be/SBcH_beH3nw
(b) http://youtu.be/SBcH_beH3nw
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1.21 Figure 2.11.5
Two pendulums from which are suspended charges of the same sign. We artificially
terminate the field lines at a fixed distance from the charges to avoid visual confusion
http://youtu.be/oFAWh4wgPbo
1.22 Figure 2.11.6
Two pendulums with suspended charges of opposite sign.
http://youtu.be/CIGLshVujjM
Figure 5.5.1 Creating an electric dipole. (a) Before any charge separation. (b) Just
after the charges are separated.
(c)
A long time after separation.
http://youtu.be/zIIQNZ9OAF0
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1.23 Figure 5.5.2
Creating the electric fields of two point charges by pulling apart two opposite charges
initially on top of one another. We artificially terminate the field lines at a fixed distance
from the charges to avoid visual confusion.
http://youtu.be/CIGLshVujjM
1.24 Figure 5.5.3
Creating (http://youtu.be/O5fHvc4Edvg ) and destroying (http://youtu.be/5G7j0d88NGc )
electric energy.
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1.25 Figure 5.7.1
(a) A negative charge and (b) a positive charge move past a massive positive particle at
the origin and is deflected from its path by the stresses transmitted by the electric fields
surrounding the charges.
(a)
http://youtu.be/C1r9-56vbio
(b) http://youtu.be/pNgFql43OvM
1.26 Figure 5.7.2
Four charges interacting via the Coulomb force, a repulsive Pauli force at close distances,
with damping.
http://youtu.be/EMj10YIjkaY
1.27 Figure 8.6.1
Two frames of an animation of the magnetic field around a positive charge moving out of
the page in a time-changing magnetic field that points downward. The blue vector is the
magnetic field and the green vector is the force on the point charge.
http://youtu.be/zjy9b_PLvbw
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1.28 Figure 8.6.2
Two views of a charged particle moving in a magnetic field that is non-zero over the pieshaped region shown. The external field is upward.
(a) http://youtu.be/eDojdmQ5sbY
(b)
http://youtu.be/a69-qC0S87U
1.29 Figure 8.6.3
A wire carrying current out of the page and free to move impinges on a region with a
constant upward magnetic field.
http://youtu.be/jIbhrRs5Q-Q
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1.30 Figure 8.6.4
A magnetic dipole in the form of a dip needle oscillates in the magnetic field of the Earth.
http://youtu.be/hnCFz8N7Juk
1.31 Figure 8.6.5
A magnetic dipole in the form of a dip needle oscillates in the magnetic field of the Earth.
We show the currents that produce the earth’s field in this visualization.
http://youtu.be/2Ub4MMEWWn0
1.32 Figure 9.1.7
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The magnetic field of (a) a moving positive charge and of (b) a moving negative charge
when the speed of the charge is small compared to c.
(a) http://youtu.be/JmqX1GrMYnU
(b) http://youtu.be/Apde4g619RA
1.33 Figure 9.1.8
The magnetic field of four charges moving in a circle. We show the magnetic field
vector directions in only one plane. The bullet-like icons indicate the direction of the
magnetic field at that point in the array spanning the plane.
http://youtu.be/-ylqucmTd00
1.34 Figure 9.2.1
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Current-carrying parallel wires can repel or attract each other.
(a) http://youtu.be/rU7QOukFjTo
(b) http://youtu.be/rU7QOukFjTo
1.35 Figure 9.2.2
(a) The attraction between two wires carrying current in the same direction. The
direction of current flow is represented by the motion of the orange spheres in the
visualization. (b) The repulsion of two wires carrying current in opposite directions.
(a) http://youtu.be/nQX-BM3GCv4
1.36 Figure 9.9.3
(b) http://youtu.be/5nKQjKgS9z0
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(a) Magnetic field of the Helmholtz coils where the distance between the coils is equal to
the radius of the coil. (b) Two co-axial wire loops carrying current in the same sense are
attracted to each other.
(a) http://youtu.be/DNbSICRSbeU
(b) http://youtu.be/rUL71B6gGd8
1.37 Figure 9.9.6
(a) Magnetic field due to coils carrying currents in the opposite directions. (b) Two coaxial wire loops carrying current in the opposite sense repel each other. The field
configurations here are shown using the “iron filings” representation. The bottom wire
loop carries twice the amount of current as the top wire loop.
(a)
1.38 Figure 9.9.7
http://youtu.be/SD4fq8wPee0
(b) http://youtu.be/9Ug-VxtCsSw
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A magnet in the TeachSpin™ Magnetic Force apparatus when the current in the top coil
is counterclockwise as seen from the top.
http://youtu.be/2TWYhylF4K4
1.39 Figure 9.9.8
Magnet oscillating between two coils.
http://youtu.be/poChtIhICuQ
1.40 Figure 9.9.9
Magnet suspended between two coils carrying currents in the same direction.
http://youtu.be/mHX7v0mgTak
1.41 Figure 10.1.2
Electromagnetic induction experiment
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http://youtu.be/tb6LywqnhBI
1.42 Figure 10.1.3
Visualizations of the total magnetic field when (a) the magnet is moving toward the coil
and (b) when the magnet is moving away from the coil.
(a)
http://youtu.be/vcG2wv6IZ8k
(b) http://youtu.be/NWE9SCRgBv0
1.43 Figure 10.4.5
A magnet falls on the axis of a stationary conducting loop
http://youtu.be/LSMdsabj0aQ
1.44 Figure 11.3.1
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Creating (http://youtu.be/GI2Prj4CGZI ) and destroying (http://youtu.be/iesoHVfIg6I )
magnetic field energy.
1.45 Figure 13.8.5
Radiation from an electric dipole whose dipole moment varies by 10%.
http://youtu.be/tZRN4rrmOuI
1.46 Figure 13.8.6
Radiation from an electric dipole whose dipole moment completely reverses with time.
http://youtu.be/4vvfUs1WHPI
1.47 Figure 13.8.7
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Radiation pattern from a quarter-wave antenna: (a) The azimuthal pattern at one instant
of time, and (b) the radiation pattern in one plane over the full period.
(a) http://youtu.be/znbHV9Rcz34
(b) http://youtu.be/G7sy7fNwTxM
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2 Simulations
2.1 Figure 1.8.1
A “vector field” representation of the field of two point charges, one negative and one
positive, with the magnitude of the positive charge three times that of the negative
charge.
http://peter-edx.99k.org/PCharges.html
2.2 Figure 1.8.2
A “vector field” representation of the field of two point charges, and a “field line”
representation of the same field. The field lines are everywhere tangent to the local field
direction.
http://peter-edx.99k.org/PCharges.html
2.3 Figure 1.8.4:
A “grass seeds” representation of the electric field that we considered in Figures 1.8.1
and 1.8.2.
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http://peter-edx.99k.org/PCharges.html
2.4 Figure 3.10.1
Screen Shot of Gauss’s Law Simulation
http://peter-edx.99k.org/GaussLawFlux.html
2.5 Figure 8.13.1
Screen Shot of Magnet and Coil Simulation
http://peter-edx.99k.org/FloatingCoil.html
2.6 Figure 9.14.1
Screen Shot of Ampere’s Law Simulation
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http://peter-edx.99k.org/AmperesLaw.html
2.7 Figure 9.14.1
Screen Shot of Faraday’s Law Simulation
http://peter-edx.99k.org/FaradaysLaw.html
2.8 Figure 13.15.1
Screen Shot of Generating Plane Wave Simulation
http://peter-edx.99k.org/PlaneWave.html