Transcript L 25

L 25 Electricity & Magnetism [2]
• static electricity
– the van de Graff generator
– electrostatic shielding
• lightning
• batteries and frogs legs
review – electric charge
• Matter (stuff) has two basic properties
• mass  gravitational force
• charge  electric and magnetic forces
– positive charge
– negative charge
• electric forces
• like charges repel +/+ or - / • unlike charges attract + / -
• charge is measured in Coulombs [C]
Where is the charge?
• the charge is in atoms
– positive  protons
– negative  electrons
• matter is usually electrically neutral  it
has the same amount of positive and
negative charge
• electrons can be transferred from one
object to another by rubbing (friction)
Conductors and Non- Conductors
• Metals (copper, aluminum, iron) are
conductors of electricity  that means
that charge can move through them
• Plastics, wood, ceramics, and glass are
non-conductors (or insulators)  they do
not let electricity flow through them
• You should not stick a metal fork into an
electrical outlet!
• You could stick a plastic fork into an outlet
without electrocuting yourself, but don’t
do it!
What makes conductors conduct?
• Atoms have equal numbers of positive and
negative charges, so that a chunk of stuff
usually has no net charge  the plusses
and minuses cancel each other.
• However, when you put a bunch of metal
atoms (like copper) together an amazing
thing happens  one electron from each
atom forgets which atom it belongs to.
• All the homeless electrons are free to
wander about inside the material
Current– charges moving about
If I connect a battery to the ends of the
copper bar the electrons in the copper will
be pulled toward the positive side of the
battery and will flow around and around.
 this is called current – flow of charge
copper
An electric circuit!
Duracell
+
Seeing and hearing electricity!
The capacitor
keeps charging
until it reaches
its limit.
Charge
storage
device
Capacitor
Many Batteries
Fully loaded and ready to go!
• The sudden discharging
of the capacitor is
accompanied with a big
spark and a bang 
man-made lightning!
danger
fully
charged
• A spark occurs when
there is enough energy
released to cause the
electrons in the air
molecules to be ripped
out of the molecules 
ionization
Non-conductors can
be charged too!
Even though non-conductors do not have
free electrons meandering about, they can
be charged by friction
 When you move your comb through your
hair, the friction (rubbing) between the comb
and hair can pull some of the electrons out of
your hair and onto the comb
 as a result your comb ends up with a net
negative charge and attracts your hair which
is now positive.

Charging by friction
If you rub plastic with cat’s fur, electrons
are rubbed onto the plastic making it
negative
 if you rub glass with silk, electrons are
rubbed off the glass making it positive
 the charge can be transferred to other
objects.

Attracting uncharged objects
+
+
+
+
uncharged
metal sphere
• A negatively charged
rod will push the
electrons to the far
side leaving the near
side positive.
• The force is attractive
because the positive
charges are closer to
the rod than the negative
charges
You can bend water with charge!
The water molecule
has a positive end and
a negative end.
charged rod
When a negative rod is
brought near the stream
of water, all the positive
ends of the water molecules turn to the right
and are attracted to the
negative rod.
stream of water
The Magic Wand
2x4
We can cause the 2 x 4 to move
with electric forces
The charging process
• an object is charged positive (has a net
positive charge ) if electrons are removed
from it
• an object is charged negative (has a net
negative charge) if electrons are
transferred to it
• charges can be transferred from
conductors or non-conductors but they can
only move through conductors.
Example
• 10 Coulombs of negative charge are
transferred from object A to object B. What
is the net charge on each object?
• ANSWER:
– object A has a net charge of +10 C
– object B has a net charge of -10 C.
+10 C
A
-10 C
-10 C
B
One Coulomb is a HUGE charge
• To get a charge of one Coulomb
on an object we would have to
remove
6,250,000,000,000,000,000
electrons from it!
• In the capacitor discharge demo, only
0.01 C of charge were involved.
•
Seeing the effects of charge:
the electroscope
the electroscope is a
simple device for
observing the presence
of electric charge
• it consists of a small
piece of metal foil (gold
if possible) suspended
from a rod with a metal
ball at its top
• If a negatively charged rod is placed near the ball,
the electrons move away because of the repulsion.
The two sides of the metal foil then separate.
Making Sparks:
The Van de Graff Generator
• The van de Graff generator
is a device for building up a
large electrical charge on a
metal sphere.
• The charge is generated
by friction between a
rubber belt and a roller.
• the charge on the belt is
transferred to the sphere
by a brush.
Electric Potential  voltage
9 Volt
battery
• The amount of charge on a
charged sphere can be
measured in terms of its
electric potential or voltage
• the more charge that is on the
sphere, the higher its voltage
• electric potential is measured in
VOLTS
• if I connect a 9 V battery to
the sphere and the ground, it
will have a potential of 9 V
Danger High Voltage !
• The van de Graff can
charge the sphere to
50,000 volts!
• This is enough to
cause discharges to
the surrounding air
• The sparks excite air
molecules which give
off light
Electrostatic shielding
Electrostatic shielding
• The effect of the high voltage on the van
de Graff generator stops on the outside of
the metal cage  Homer is SAFE!
• Being inside your car during a lightning
storm offers you some protection
• radio signals cannot penetrate through a
metal enclosure
• the metal bars (rebar) that reinforce the
concrete in walls can interfere also
Lightning- outdoor spark





causes 80 million
dollars in damage each
year in the US
On average, kills 85
people a year in the US
over in a thousandth of
a second
carries up to 200,000 A
causes the thunder!
development of a lightning bolt
charge
separation
stepped
leader
leader &
streamer
leader meets
streamer
lightning
bolt
applications of electrostatics
• Xerox copiers use
electrostatic attraction to
put the ink droplets on the
paper
• electrostatic precipitators
use the attraction of
charged dust to remove
dust particles from smoke.
• can be used to hold
balloons on your head
Removing soot particles
Positive
cylinder
Chimney
stack
soot
Charging units
spray electrons
on the soot
particles
Frog's leg Batteries
• in 18th century Luigi Galvani a professor of
anatomy at the University of Bologna
found that a freshly dissected frog leg
hung on a copper hook twitched when
touched by an iron scalpel.
• The two metals had to be different.
• Galvani thought that he had discovered
the secret life force
Alessandro Volta
• Professor of Physics at the University of
Pavia realized that the electricity was not in
the frog’s leg but the twitching was the
result of touching it with two different metals
• Volta had discovered the first battery.
• Lemon battery
Batteries  use chemical energy
to produce electricity
• two dissimilar metals immersed in a conducting
fluid (like an acid for example) cause a chemical
reaction which can produce electric current.
zinc
electrode
copper
electrode
acid
Inside a Duracell 1.5 Volt battery
Metal Cap
plastic case
+
Carbon center
electrode
Electrolyte
paste
Zinc outer
electrode
- Bottom
electrode