Chapter 17

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Transcript Chapter 17 

Chapter 17
Electric Forces
and
Electric Fields
Chapter 17 Objectives
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Properties of electric charges
Conductor vs Insulator
Conduction vs Induction
Polarization
Coulomb’s Law
Electric field
Electric field lines
Properties of Electric Charge
• An electric charge
• An electric charge is
negative because it
is positive because
has gained electrons
it has lost electrons
and other negatively
and other
charged particles.
negatively charged
– Represent by –
particles.
– Represented by +
– Often drawn in
red.
– Often drawn in black.
This idea was first mentioned by Benjamin Franklin (1706-1790)
Behavior of Electric Charges
• Opposite charges attract one another.
– Like charges repel.
• Electric charge is conserved.
• The transfer of charge occurs because the negative
charge is transferred from one object to another.
– So objects either gain or lose negative charge.
• In order to become positive, an object will lose a negative charge.
• Robert Millikan (1886-1953) discovered that charges
are quantized, or said to have a fundamental unit of charge.
– Meaning the charge is full integer multiples
• + e, + 2e, + 3e, etc.
Conductor v Insulator
• A conductor is a
material in which
electric charge moves
freely.
– Electrons are free to
move from atom to
atom.
• Metals are good
conductors.
• Water is a pretty good
conductor.
• An insulator is a material in
which electric charge does
not move freely.
– Electrons do not leave their
respective atoms
– Can maintain a charge, but
only at the surface and it
does not transfer to other
regions of the material.
• Glass, rubber, wood are good
insulators.
– Natural fibers are usually
good insulators.
• Humans can be good
insulators.
Conduction v Induction
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Conduction occurs between
objects in contact with each
other.
• The object being charged has no
way for the charge to escape once
it is being charged.
• The object doing the charging
loses charge that is gained by the
other object.
– That way the newly charged
object is left with the same
charge of the other object.
• Induction occurs between two
objects not in contact with each
other.
• The object being charged does
have a path for charges to escape.
– That is because the object is
grounded, or attached to the
unlimited supply of electrons in
the Earth.
• Induction lines opposite charges up
along the surface of the objects.
– This pushes the electrons toward
the grounded surface and the
charge flows into the Earth.
Polarization
• The shifting of the centers of charge to
favor one side of a molecule or the other is
called polarization.
• This often occurs in insulators.
• Also occurs in water because of the unique
molecule arrangement between oxygen and
hydrogen.
Coulomb’s Law
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Charles Coulomb (1736-1806) established the
fundamental laws that govern electric force
between two stationary charged sources
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2.
3.
The electric force is inversely proportional to the
square of the separation, r, between the charges.
The electric force is proportional to the product of
the magnitudes of the charges, |q1| and |q2|
It is attractive if the charges are of opposite sign and
repulsive if the charges have the same sign.
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So you add the sign in after working the computations.
Coulomb the Electrical Newton?
• Coulomb’s Law is the electrical equivalent of Newton’s
Universal Law of Gravitation.
– Remember that stated there was an attractive force between all
objects depending on mass and separation.
• The set up is the same and must fit the laws stated by
Coulomb’s Law
F=
kC
Lowercase q stands for charge
(q1)(q2) Measured in Coulombs (C)
r2
r is the separation between charges
kC is the Coulomb Constant and is equal to 8.99 x 109 N•m2/C2
e- = -1.60 x 10-19 C
e+ = 1.60 x 10-19 C
e+ is called a proton
The Electric Field
E=
• Charged particles can have a varying effect on each other in
space.
– Touching or not touching!
• This effect was best described by Michael Faraday (1791-1867).
• An electric field exists in the region of space around a
charged object.
– When another charged object enters this region, an electrical force
becomes present between them.
• The direction of the field always points from positive to
negative.
• The strength of the field is defined as the magnitude of the
electric force divided by the magnitude of its charge.
– SI Units: N/C
q0 is the reference charge, or center of the charge pattern
F
q0
Electric Field From a
Single Point
• Another way to calculate the electric field
generated by single point charge is to ask for the
help of Coulomb’s Law
– Use this formula if the electric force is unknown.
E=
F=
q0
E = kC
q
r2
kC
|q| |q0|
r2
q0
Electric Field Lines
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Remember that the electric field points in a
direction from positive to negative.
An electric field line shows the path and
magnitude of the electric field present
around a single point charge.
1. Lines always point straight away from charge
2. The number of lines per unit area identify the
field strength
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The field is larger when the lines are closer
together.
Drawing Field Lines
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Follow these rules for drawing
field lines
1.
Lines must begin at positive and end
at negative.
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2.
-
+
+
If there is no positive, start at
infinity.
If no negative, end at infinity.
The number of lines drawn is
proportional to the magnitude of
the charge.
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3.
+
More lines, larger the charge.
No two field lines cross each other.
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They may connect, but they never
cross.
Electrostatic Equilibrium
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When no net motion of charge occurs within a
conductor, the conductor is said to be at
electrostatic equilibrium.
An isolated conductor (Insulated from ground) has the
following properties:
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Electric field is zero inside the conductor.
All charge resides entirely on its surface.
Electric field just outside a charged conductor is
perpendicular to the surface.
On irregularly shaped conductors, the charge tends to
accumulate at locations of the smallest radius of
curvature, or tightest corners.