|
|
 
|
The electrical force is so pervasive that it is
difficult to name many aspects of the physical world not affected by
it. At the most fundamental level, the attractive electrical force
between electrons and protons holds atoms together. On a bit larger
scale, electrical interactions between atoms are responsible for the
formation of molecules. On a much grander scale, a rapid discharge
of atmospheric electricity manifests itself as a flash of lightning.
All these phenomena are governed by the same basic principles.
Though every student has had direct experience with static charges
(who hasn’t been zapped after walking across a carpet?), few
understand the mechanisms underlying electrostatic phenomena. The
collection of activities that follow are designed to spark interest
in learning about electricity.
~
Chris
Chiaverina
|
|
 |
Here's a great reason to discuss
static electricity with students, just watch this video clip!
Static charge ignited gas fire video
(Windows Media Player File clip has
no sound) |
|
What's the
Charge!
Concept: When two different
substances are brought into contact, electrons may be transferred
from one substance to another. When this occurs, the materials are
said to be charged. The material that gains excess electrons is said
to be negatively charged; the material with a deficit of electrons,
positively charged.
Rub an inflated balloon against a piece
of fur, wool or cotton. Does the balloon become charged? To see,
bring the balloon near some tiny bits of paper as a test. What
happens as you approach the pieces of paper?
Try charging other materials by rubbing them together. The
possibilities are limitless! As you test various pairs of materials,
make a list of the pairs that seem to work best. |
Get information on Electrostatic Friction
items here |
|
When you rub a balloon with fur, wool,
or cloth, does the balloon acquire a positive or negative charge?
One way to find out is to produce a “test charge” by rubbing a
rubber rod with fur. Benjamin Franklin’s named the charge on the
rubber rod “negative” and the charge on the fur “positive.” This
nomenclature remains with us to this day. With this in mind, devise
a way to use the rubber rod to determine the nature of the charge on
the balloon.
The charge on an object may also be determined by consulting the
triboelectric series, a ranking of materials based on their tendency
to give up electrons. Examine this series, which can be found at:
|
|
Sticky
Business
Concept: Like charges repel; unlike
charges attract.
Remove two 6 inch strips of transparent
tape from a roll. Hold the two pieces of tape close to each other
with their sticky sides facing outward. Is there an interaction
between the two pieces of tape? If so, is it attractive or
repulsive? What does this tell you about the charge residing on the
pieces of tape? (Hint: The pieces of tape are essentially identical
and were electrified in the same way.)
|
 |
|
Now fold over a couple of centimeters of
tape to form a tab at the end of each strip. This will provide a
non-sticky finger hold. With the adhesive side down, attach one
strip to a smooth table top. Make sure the tab protrudes over the
edge of the table. Place the second strip of tape on top of the
first, again with adhesive side down. Quickly remove the top strip
of tape. Then remove the tape that is attached to the table. Bring
the two pieces of tape close to one another with their sticky sides
facing outward. What do you observe? What does this tell you about
the charges on the two strips of tape? Can you explain the how the
strips may have become charged the way they did?
|
|
Homemade
Electroscope |
Foiled Again!
Concept: The electroscope is a
device that can be used to detect the presence of an electric
charge. An electroscope’s operation is based on the principle of
like sign charge repulsion.
There are a number of simple
electroscopes that you can build out of household materials.
Instructions for making one type of electroscope are given below.
Once you have constructed your electroscope, you may use the device
to perform a number of electrostatic experiments. For example try
the experiments Charging by Contact and Inductive Reasoning
described below. |
|
The electroscope shown below is constructed from an empty
soda can, a Styrofoam cup, two strips of aluminum foil, and some
tape. Tape the soda can to the bottom of an inverted Styrofoam cup.
Cut two strips of aluminum foil each about 5 cm long and 5 mm wide.
Bend one end of each of the strips to form hooks. Using the hooks,
hang the strips of aluminum foil, one on top of the other, from the
extended can tab. Your electroscope is now ready for use!
|
|
Charging by
Contact
Concept:
Neutral conductors can be
charged by conduction if they come in contact with charged objects.
Rub a balloon on a piece of wool or cotton. Bring the balloon in
contact with the electroscope. What happens to the aluminum strips?
Now remove the balloon. Describe the behavior of the strips when the
balloon is withdrawn. Can you explain the behavior of the strips?
Now put the balloon down and touch the can with your finger. This
process is called “grounding.” By touching the electroscope with
your finger, you have provided a conducting path for the residual
charge on the electroscope. What happens to the strips of aluminum
when you touch the electroscope? Why do you think the strips behave
this way?
|
|
Inductive
Reasoning Parts 1 and 2
Part 1: A Trial Separation
Concept: A charged object can
induce charge separation in a neutral object.
Watch the electroscope’s aluminum strips as you bring a charged
object, such as a balloon, near the bottom of the can in the
electroscope. How do the strips behave as the charged object gets
closer? What happens to the aluminum strips as the charged object
gets further away? Explain your observations.
Part 2: A Permanent
Split
Concept: An object may be
given a residual charge by induction. An object charged by induction
acquires a charge opposite in sign to that of the object inducing
it.
Bring a charged object near the electroscope. Be certain not to make
contact with the electroscope. With the charged object near the
electroscope, touch the electroscope with a finger from your free
hand. Remove your hand before removing the charged object. What
happens to the aluminum strips when your hand is withdrawn? Now
remove the charged object. What happens to the strips now? Why does
this occur? How does the sign of the charge on the electroscope
compare to the sign of the charge on the external object? How can
you test your answer?
|
|
Get details on Electroscopes and Pith Balls here |
Get information on Friction Rod sets here |
|
|
|
“Board” with Electrostatics? Attracting an Uncharged Insulator
Concept: A charged object of either sign will attract an
uncharged insulator.
Balance a 2 X 4 board on an inverted
watch glass. The watch glass provides a low-friction support for the
board. Charge a balloon by rubbing it with wool or cloth. Bring the
charged balloon near, but not touching, one side of the board. The
closer the balloon is held to the end of the board, the better. What
effect does the charged balloon have on the board? Once the board is
in motion, move the balloon to the other side of the board. Does the
balloon attract the other side of the board? How do you know?
Charge the balloon once again, but this time, bring the wool or
cloth used for charging near the end of the board. What happens?
What does this tell you about the condition of the wool or cloth?
|
|
 |
Try a smaller
version...
Place an empty aluminum soda can on a
table top. Bring a charged object, for example a balloon, near, but
not touching the can. What happens? Explain why this is occurring.
Once the can is rolling, how can you stop it with the charged
object?
Will an object with a charge opposite that of the balloon or tube
have the same effect on the can? To find out, you can experiment
with the wool or cloth used in the charging process.
|
|
 |
|
Pretty Cagey
Concept: Excess charge on an
isolated conductor is located entirely on the outer surface of the
conductor. As a result, there are no electrical effects inside a
conductor.
Turn on a small
battery-powered radio and tune it to an AM station. Lower the radio
into a coffee can or a cage fashioned from screen wire or aluminum
foil. Can the sound still be heard when the radio is in the
container? How can this effect be explained?
The metal surrounding the
radio in this demonstration is often referred to as a Faraday cage.
A Faraday cage is an enclosure of metal or metallic meshwork. If a
region in space is completely surrounded by a Faraday cage,
electromagnetic waves are effectively screened from the enclosed
region. Likewise, electromagnetic effects produced inside the cage
cannot permeate the enclosure. Named for physicist Michael Faraday,
who built the first one in 1836, Faraday cages may be found in a
variety of settings.
A common example of a Faraday Cage is a
metal automobile body. Contrary to a common belief, you are safe in
a car during an electrical storm not because of the rubber tires but
because of the shielding effect of the metal that surrounds you.
Bridges supported by metal girders may interfere with a car radio’s
reception for the same reason. Faraday cages are often used to
surround electronic components found in computing and communications
devices. These cages serve two purposes: they keep unwanted ambient
electromagnetic radiation out while at the same time containing
component-produced radiation.
|
|
Unlimited
Charging.....no, not on your credit card! |
|
Concept: The
electrophorus, an early charging device, is used for producing
electrostatic charge by induction.
An electrophorus is an amazing device for it serves as a virtually
inexhaustible source of electrical charge. Constructing an
electrophorus is very simple. All you need is an aluminum pie pan, a
Styrofoam plate and cup, some tape or hot glue. Simply attach the
Styrofoam cup to the center of the pie pan using tape or hot glue
and you’re in business (see figure)! Charging the pie pan is a three
step process:
|
 |
-
Rub the Styrofoam plate
with wool, fur or cloth.
-
Using the Styrofoam cup
as a handle, lower the pie pan onto the Styrofoam plate.
-
Touch the pie plate with
your finger. The plate is now charged!
To convince yourself
that the pie pan is charged, you can bring it in contact with the
electroscope, hold it near a thin steam of water, or give a friend a
mild shock.
You may also use the charge on the pie pan to briefly light a neon
or fluorescent lamp. Touch one terminal of either lamp with a finger
while touching the terminal with the charged pie pan.
After the pie pan is discharged, it may be charged again as many
times as you like. You don’t even have to rub the Styrofoam plate
again before charging the pie pan. Why this is possible?
An electrophorus with substantially greater charge capacity may be
constructed by replacing the pie tin and Styrofoam plate with a
large pizza pan or cookie sheet and a sheet of blue polystyrene
insulating material. This insulating material usually comes in large
sheets from home supply stores. Any plastic handle may be attached
to the larger pan with hot glue.
|
Mickey Mouse
Molecule
Concept: Some molecules are permanently electrically
polarized. That is, one side of the molecule has a little more
negative charge than the other. This polar water molecule has the shape reminiscent of a famous mouse.
Bring a charged object near a thin stream of tap water. What happens
to the stream as the charged object nears the stream? Explain why
the water is attracted to the charged object? Do you think all
liquids are attracted to charged objects?
|
|
|
 |
Getting a Charge
Out of Television?
This next next demo is courtesy of Simon
Quellen Field and www.Sci-Toys.com |
|
Concept:
The screen of an operating television is charged. As with an
electrophorus, an object brought close to the screen can be charged
by induction.
A simple electrostatic motor may be constructed from two empty soda
cans, a short length of thread, a plastic pen, two square feet of
aluminum foil, and two connecting wires. After removing the tabs
from the cans, tie the thread to one of them; discard the other tab.
Tie the other end of the thread to the plastic pen. Use the cans,
separated by about three inches, as supports for the pencil. Tape
the bare end of one wire to the can on the left. Connect the other
end of the wire to ground (e.g. a water faucet). Use the second wire
to connect the can on the right to the aluminum foil.
After turning on your television set, press the aluminum foil onto
the screen. Electrostatic attraction will keep the foil in place
after removing your hand. The tab should begin swinging back and
forth between cans.
Simon's web site has tons of demo and project ideas for students,
teachers and parents. This one is called "A high voltage motor in 5
minutes". Complete details can be found at:
http://www.scitoys.com/scitoys/scitoys/electro/electro4.html#franklin
|
|
|
|
|
Get details on the Arbor Scientific Hand Crank Van de Graaff
Generator
|
Get details on the powered Van de Graaff Generator
|
Van de Graaff
Electrostatic Generator
Concept: A Van de Graaff electrostatic generator is a device
that transfers charge to an insulated metal sphere by means of a
moving belt. Objects that touch the sphere acquire charge of the
same sign as the charge on the sphere.
With
the Van de Graaff generator discharged, place five to ten
disposable aluminum pie plates, face down, on the top of the
sphere. Once the plates have been positioned on the sphere, turn
the generator's hand crank. If the generator has an electric
motor, turn the generator on with the switch. What happens to
the plates as the sphere becomes charged? Explain why the plates
behave this way.
|
|
Did You Know.... |
|
Benjamin Franklin was one of the most
extraordinary human beings the world has ever known. Most agree that
he was a genius for he was adept at writing, diplomacy, business,
music, humor, leadership and, last but certainly not least, science.
When one thinks of Benjamin Franklin the
first thing that usually comes to mind is an image of his
death-defying attempt to demonstrate the electrical nature of
lightning. Consistent with this mental picture of America’s first
scientist, Franklin did indeed fly a kite up into a thundercloud and
drew sparks from a key tied to the bottom of a wet string. He was
fortunate to escape electrocution throughout his experimentation
with lightning for it is reported that during one experiment he
received such a severe electrical shock that his body went into
seizures.
In addition to confirming that lightning
was an electrical phenomenon, Franklin managed to sort out many of
the mysteries of static electricity that had puzzled people for
ages. After observing that a glass rod becomes charged when it is
rubbed with a piece of cloth, he postulated that an equal amount of
charge of the opposite kind collected on the cloth. This led to what
is now known as the conservation of charge. Franklin also invented
the lightning rod and coined many of the electrical terms we use
today, such as conductor, condenser, positive and negative charge,
electric shock and electrician.
|
|
|
|
New !
CoolStuff Cool~Pic:
Lightening Strikes! This image is courtesy of the Museum of Science
in Boston. This is their giant Van de Graaff generator, and yes,
that's a guy in the screen cage reaching for the spark! (
Spark seems like the wrong term for
this shot! ) See the link
below to visit the museum web site.
|
|
Interesting
Links:
Here are details a
real simple Van de Graaff generator:
http://web.singnet.com.sg/~sengam/construction.htm
|
|
Next Issue:
“Whoever wishes to get a true appreciation of the greatness of
our age should study the history of electrical development.
There he will find a story more wonderful than any tale from
Arabian Nights.” Nikola Tesla, 1915
Even scientist, inventor, and visionary Nikola Tesla couldn’t
have possibly imagined the role electricity would one day play
in our lives. Today most everything we use is powered by
electricity. If you have a moment, try to list all the
electrical devices you use in any given day. I assure you, you
will be amazed. We are often not even aware of our use of these
devices. For example, did you know that the average automobile
contains over 50 electrical motors?
Inexpensive and
readily available, electrical energy is in large part
responsible for the quality of life that many of us take for
granted. It is imperative that our students become aware of the
importance of electricity in their lives and gain at least a
rudimentary understanding of the physical principles governing
charges in motion. In “Current Topics”, our next edition of
CoolStuff, we will present some activities designed to tap your
students electrical potential
Regards,
|
|
|
|
Subscription information
You have received this email as a customer of Arbor Scientific, because you
have opted into the newsletter mail list, or because you have requested
information from Arbor Scientific. We would love to hear from you, and find
out what you think of our newsletter "Cool Stuff". You can click on the link
below to leave your comments, receive messages tailored to your interests,
and update your profile at
http://www.arborsci.com
/Customer_Service.htm .
To unsubscribe click here:
unsubscribe
To send this email to a friend just click on the link
and
include the email address in the body of the message:
Send Now
Email addresses will not be shared with third parties.
© 2006 Arbor Scientific
|
|
|