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CHAPTER 27
EINSTEIN’S Relativity
LENGTH CONTRACTION
TIME DILATION
SIMULTANEITY
RELATAVISTIC MASS
GENERAL RELATIVITY
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The transformation equations before
Einstein �� = � − �� �� = �
� =
�� = �
These are the Galilean Equations that allow
observers to compare observations in two
different frames moving relative to each
other with constant velocity.
From these equations we get the addition
of velocities transformation equation.
� = − �
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Consider the two speeds, each measured in
a different reference frame:
A policeman on the side of the road
measures your speed with radar:
Another policeman driving towards you at
speed � measures your speed: �
The two speeds are related by this equation
� = − �
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Consider that you are going 80 mph and the
moving policeman is going 20 mph (towards
you). Take the direction the policeman is
going as the � direction.
Use � = − �
Then � = 20 �ℎ = −80 �ℎ
What does the moving policeman measure
for your speed?
� = �−80 �ℎ − 20 �ℎ� = 100 �ℎ
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Einstein’s postulates for the Special Theory
of Relativity:
1. Fundamental laws of physics are identical
for any two observers in uniform relative
motion.
2. The speed of light is independent of the
motion of the light source or observer.
These postulates cannot be satisfied using
the Galilean Equations.
However Einstein found that the following
equations worked.
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�� = ��� − ��� �� = �
� =
�� = � �� −�����
� = 1�1 −����
These are the Lorentz Transformation
Equations.
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LENGTH CONTRACTION
Consider an observer on a railroad car with
a rod of length L0. (L0 is called proper length
because it is at rest relative to the observer.)
He measures the length of the rod to be
��� −��� =�
Use the Lorentz equations to get
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��� = ���� − ����
And
��� = ���� − ����
Then putting these in the equation
For proper length.
� = ���� − ���� − ���� − ���� � = �!��� −��� − ���� − ���"
If the observer on the ground measures the
far end and near end of the rod at the same
time
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�� = ��
Then
� = ���� −��� = ��
Or
� = #$% and � > 1
So the observer on the ground with the rod
moving past in the x direction measures the
rod to be shorter than what is measured by
the observer at rest relative to the rod and
on the car.
Length Contraction is a prediction of the
Lorentz Equations.
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TIME DILATION
Again we will find time dilation a different
way than the book.
Observer on railroad car moving in direction
with firecrackers and another observer on
ground.
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The firecracker at �� explodes and then
some time later the one at �� explodes.
We will consider the time between the two
events.
The time interval between the two events
as measured by the observer on the ground
will be
∆� = �� −��
The transformation equation for time is
�� = � �� −�����
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Which for the other observer is
� = � (�� +����� *
Therefore we get for �� and ��
�� = � (��� +������ *
And
�� = � (��� +������ *
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Put these into the time interval equation
∆� = � (��� +������ * − � (��� +������ *
Or ∆� = � +���� − ���� + ��� ���� −����,
Or ∆� = � +∆�� + ��� ���� −����,
The time interval is different for the two
observers.
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For simplicity consider the two firecrackers
at the same place
��� =��� =��
Then
∆� = � +∆�� + ��� ��� −���,
Or ∆� = �∆��
And � > 1
The time interval for the observer on the
ground with the events moving relative to
her is longer.
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MOVING CLOCKS RUN SLOWLY
If an observer is moving relative to a clock
the interval between ticks will be longer.
This is Time Dilation
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Einstein / Lorentz Transformation Equations
1. Satisfy Einstein’s Second Postulate
2. Predict Length contraction
3. Predict Time Dilation
But are these correct?
Theories are not worth much if they are not
supported by experiment!
Must have an experiment to prove!!!
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Muon “lifetime” Experiment
Muons are particles created high in our
atmosphere.
They rain down continuously at high
velocity at approximately
� = 2.994�100 /2
If at rest they only exist for approximately
3 = 2�104526�7892
The experiment is to set up a detector at
the top of a mountain and stop the muons
in the detector and measure how long they
exist.
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Then ask how far down would they have
traveled if they had not been stopped in the
detector.
distance = (speed) x (time they exist)
9 = �2.994�100 /2��2�10452� = 600
If the mountain is 2000m tall, in the valley
at the bottom of the mountain should
find very few if any muons.
Move the apparatus to the bottom of the
mountain and measure the number of the
same type muons that reach sea level.
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The experiment showed that almost as
many reached sea level as passed through
the atmosphere at the level of the top of
the mountain.
Why?
When moving relative to us the observer
they exist not for
3 = 2�104526�7892
But for
3 = �� = 3;1 −<2.994�1003�100 >�
3 = 32�10452
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Thus distance traveled will be
9 = �2.994�100 /2��32�10452� 9 = 10,000
Well below sea level, thus almost all muons
should reach sea level.
Confirming Time Dilation
What about Length Contraction?
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