Fig 29-CO, p.895
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Slide 1 Fig 29-CO, p.895
Slide 2
The direction of the magnetic field B at any location is the direction
in which a compass needle points at that location.
the magnetic field lines outside the magnet point away from north
poles and toward south poles.
Slide 3
We can define a magnetic field B at some point in space in terms
of the magnetic force FB that the field exerts on a test object, for
which we use a charged particle moving with a velocity v.
assuming that no electric (E) or
gravitational (g) fields are present at the
location of the test object.
Slide 4
• The magnitude FB of the magnetic force exerted on the particle is
proportional to the charge q and to the speed v of the particle
• The magnitude and direction of FB depend on the
velocity of the particle V and on the magnitude and
direction of the magnetic field B.
• When a charged particle moves parallel to the magnetic
field vector (i.e., θ = 0) , the magnetic force acting on
the particle is zero.
• When the particle’s velocity vector makes any angle with
the magnetic field, the magnetic force acts in a direction
perpendicular to both v and B; FB is perpendicular to the
plane formed by v and B
Slide 5 Fig 29-3b, p.897
• The magnetic force exerted on a positive
charge is in the direction opposite the direction
of the magnetic force exerted on a negative
charge moving in the same direction.
• The magnitude of the magnetic force exerted
on the moving particle is proportional to sin ,
where is the angle the particle’s velocity vector
makes with the direction of B.
We can summarize these observations by writing the magnetic force in the form
Slide 6
Slide 7 Fig 29-6, p.901
Slide 8
An electron in a television picture tube moves toward the front of the tube with a
speed of 8.0 x 106 m/s along the x axis. Surrounding the neck of the tube are
coils of wire that create a magnetic field of magnitude 0.025 T, directed
at an angle of 60° to the x axis and lying in the xy plane. Calculate the magnetic
force on and acceleration of the electron.
Slide 9
3- An electron moving along the positive x axis perpendicular to
a magnetic field experiences a magnetic deflection in the
negative y direction. What is the direction of the magnetic field?
Slide 10
5- A proton moves in a direction perpendicular to a uniform
magnetic field B at 1.0 x107 m/s and experiences an acceleration
of 2.0x1013 m/s2 in the + x direction when its velocity is in the +z
direction. Determine the magnitude and direction of the field.
Slide 11 Fig 29-7, p.901
If a magnetic force is exerted on a single charged particle when the particle moves through a magnetic field, it should not surprise you that a current-carrying wire also experiences a force when placed in a magnetic field.
the current is a collection of many charged particles in motion; hence, the resultant force exerted by the field on the wire is the vector sum of the individual forces exerted on all the charged particles making up the current.
The force exerted on the particles is transmitted to the wire when the particles collide withthe atoms making up the wire.
Slide 12 Fig 29-7a, p.901
Slide 13 Fig 29-8, p.901
Slide 14
15- A wire having a mass per unit length of 0.500 g/cm carries a
2.00-A current horizontally to the south. What are the direction and
magnitude of the minimum magnetic field needed to lift this wire
vertically upward?
Slide 15
14- A conductor suspended by two flexible wires as shown in
Figure P29.16 has a mass per unit length of 0.040 0 kg/m. What
current must exist in the conductor for the tension in the
supporting wires to be zero when the
Magnetic field is 3.6T into the page ? what is
The requid direction for the current?
Slide 16
# The magnetic force acting on a charged particle moving in a magnetic
field is perpendicular to the velocity of the particle and consequently the
work done on the particle by the magnetic force is zero.
(W= F.S= Fs cos (W= F.S= Fs cos θθ))
# Because FB always points toward the
center of the circle, it changes only the
direction of v and not its magnitude.
# the rotation is counterclockwise for a
positive charge. If q were negative, the
rotation would be clockwise.
Slide 17
The angular speed of the particle
The period of the motion T (the time that the particle takes to complete one revolution) is equal to the circumference of the circle divided by the linear speed of the particle:
Slide 18
A proton is moving in a circular orbit of radius 14 cm in a uniform 0.35-T
magnetic field perpendicular to the velocity of the proton. Find the linear
speed of the proton.
Slide 19
1- Velocity Selector:
Slide 20
Only those particles having speed v pass un-deflected through the mutually
perpendicular electric and magnetic fields. The magnetic force exerted on
particles moving at speeds greater than this is stronger than the electric
force, and the particles are deflected upward. Those moving at speeds less
than this are deflected downward.
Slide 21
Slide 22
Slide 23
Slide 24
Slide 25 Fig 29-20, p.909
Slide 26 Fig 29-21, p.910
Slide 27 Fig 29-22, p.910
Slide 28 Fig 29-23, p.911
Slide 29 Fig 29-23a, p.911
Slide 30 Fig 29-23b, p.911
Slide 31 Fig 29-24, p.911
Slide 32 Fig 29-25a, p.912
Slide 33 Fig 29-25b, p.912
Slide 34 Fig 29-26, p.912
Slide 35 Fig 29-27a, p.913
Slide 36 Fig 29-27b, p.913
Slide 37 Fig 29-28, p.914
Slide 38 Fig 29-29, p.915
Slide 39 Fig 29-29a, p.915
Slide 40 Fig 29-29b, p.915
Slide 41 Fig Q29-9, p.917
Slide 42 Fig P29-17, p.918
Slide 43 Fig P29-1, p.918
Slide 44 Fig P29-1a, p.918
Slide 45 Fig P29-1b, p.918
Slide 46 Fig P29-1c, p.918
Slide 47 Fig P29-1d, p.918
Slide 48 Fig P29-14, p.919
Slide 49 Fig P29-15, p.919
Slide 50 Fig P29-17, p.919
Slide 51 Fig P29-18, p.920
Slide 52 Fig P29-23, p.920
Slide 53 Fig P29-48, p.922
Slide 54 Fig P29-53, p.922
Slide 55 Fig P29-55, p.922
Slide 56 Fig P29-59, p.923
Slide 57 Fig P29-61, p.923
Slide 58 Fig P29-63, p.923
Slide 59 Fig P29-64, p.923
Slide 60 Fig P29-66, p.924
Slide 61 Fig P29-69, p.924
Slide 62 Table P29-70, p.924
Slide 63 Fig P29-71, p.924
Slide 64 Fig P29-72, p.925
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