Reason For Testing:
A
reason someone might want to test the speed of light in their home is to make
something more interactive and engaging as well as testing science theories
themselves. If for some unusual reason the speed of light were to become
unstable then you could test it in your kitchen and become a science genius.
Research:
The
research involves some key concepts:
What is a wave?
Webster's
dictionary defines a wave as "a disturbance or variation that transfers
energy progressively from point to point in a medium and that may take the form
of a variation of pressure, electric or magnetic intensity, electric potential,
or temperature."
What is an electro-magnetic wave?
Electro-magnetic
waves are radiation consisting of waves of energy associated with electric and
magnetic fields resulting from the acceleration of an electric charge.
There
is a range of frequencies in electromagnetic waves from visible light (low
frequency) throught to gamma rays (high frequency. Light is only a tiny section
of the electromagnetic spectrum. Microwaves have their own spectrum of
electromagnetic waves (see Figure 2).
Electromagnetics
waves can travel through vacuums (stuff with no matter) which means they don’t
need an external medium. This is different to sound waves as sound waves are
mechanical waves which means they need water or air to travel through.
For
this experiment we need to find the frequency of the microwave because this
frequency can be used to calculate the speed of light. If we can find the distance
between the waves (the wave length) and figure out how many waves pass every
second (frequency), then we can calculate how far light travels every second
and therefore we can get an approximate measurement of the speed of light.
Note:
Hertz (Hz) and Megahertz (MHz) are units
of measurement for wave frequencies.
Also,
frequencies are invertedly proportional to wavelength so long wavelengths have
a short frequency and short waves have a high frequency.
To
test the speed of light I tested some of the physical properties of waves - wavelength, frequency and interference.
The
interference is the electromagnetic waves bouncing off the surface of the edge
of the microwave in combination with the new waves that are being created. Some
are also lost in the process which also create interference. These lost waves
can be heard through my radio which was near the microwave at the time.
The
interference can be seen as hotspots and coldspots in the microwave. This is
why microwaves have rotating platters, to spread the heat evenly. Each cold spot (the part of the food that
isn’t cooked) is equal to half a wavelength (see Figure 1 for more details). If
we take out the rotating platter we can find the hot spots and therefore find
the wavelength
We
can find the size of the wave length by finding the distance between the
uncooked portions of the food (Figure 1). If we multiply that by two we get the full
wave length of the microwave.
We
have to cook the food just right so that some bits have solidify. The egg white
will cook fastest in the hot areas (See Figure 1).
I
will be testing egg whites in the microwave as these are relatively easy to
identify the wavelength of this material.
Figure 1
Frequency x Wavelength (metres) =
Speed Of Wave
Aim:
To find the speed of light
To use equipment found at home to
measure the speed of light.
Hypothesis:
If light is one form of
electro-magnetic radiation and microwaves produce electro-magnetic radiation,
then we should be able to measure the speed of light approximately using a microwave.
Equipment:
●
Microwave
●
Eggs (egg white) 3 - 6
●
Plate
●
Ruler
●
Calculator
Safety:
●
Oven Mitts
Information:
●
Frequency
Method:
1. Find frequency of microwave oven
Mine was 2450MHz
which seems to be a standard for microwave ovens but they do vary.
2. Remove rotating platter from
microwave.
This is to
stop heat from spreading evenly which would cancel out hot spots.
3. Crack an egg and pour the egg whites in the
middle of the plate.
Egg white
shows the wavelengths well. Alternatively you can use bread with butter or
chocolate to test as well.
4. Place plate in center of oven.
5. Cook materials.
30 seconds in
the microwave seems to show the hotspots well.
6. Measure the space between the
cooked and uncooked material to find the wave length.
The uncooked
space in between is equal to half a wavelength.
7. Test multiple times.
8. Record results.
Calculate:
9. Frequency (MHz) x Wave Length
= Speed Of Light
Results:
Eggs Test
|
Average Length 1/2 Wave (cm)
|
Speed of Light
(m/s)
|
Accuracy
|
Test 1
|
6.25
|
306250000
|
97.89%
|
Test 2
|
6
|
294000000
|
98.07%
|
Test 3
|
5.75
|
281750000
|
93.98%
|
|
|
|
|
Average Result From Tests (m / s)
|
6
|
294000000
|
98.07%
|
Actual Speed Of Light m / s
|
6.11821345cm
|
299792458
|
100%
|
M/s=
metres per second
Calculations:
Discussion:
● I think that this experiment was a fair test.
Some of the
difficulties I encountered arose in measuring the wavelength accurately with a
ruler. This could affect the results a lot because small changes in measurement
are big when multiplied by 2450 MHz.
I felt that after
three tests I didn’t need to do any more. I was getting effectively the same
results every time and as it turned out the measurements were quite accurate. I averaged the results to obtain a
measurement.
Conclusion:
I consider like
my hypothesis was correct. The average result/calculations was only off by
about 1.93% which is very close considering I used household items and products
to obtain a measurement of the speed of light.
If
you were to get more accurate with your measurement then you could probably measure
the speed of light better - marginal differences have big effects. This project
is good because it shows us that things in the home that surround us can be used
to measure the speed of light.
Bibliography:
Tran, T. (2009). Guide to science
fair. NIWA Wellington Regional Science & Technology Fair. Retrieved from
http://www.sciencefair.org.nz/files/A%20Student%20Guide%20to%20the%20Science%20Fair1%20V3.pdf