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Doppler Effect in Light
Red & Blue Shift
by Andrew Zimmerman
Jones
Light waves from a moving
source experience the Doppler effect to result in either a red shift or blue
shift in the light's frequency.
This is in a fashion similar
(though not identical) to other sorts of waves, such as sound waves.
The major difference is that
light waves do not require a medium for travel, so the classical
application of the Doppler effect doesn't apply precisely to this
situation.
Relativistic Doppler Effect for Light
Consider two objects: the
light source and the "listener" (or observer).
Since light waves traveling in
empty space have no medium, we analyze the Doppler effect for light in terms of
the motion of the source relative to the listener.
We set up our coordinate
system so that the positive direction is from the listener toward the source.
So, if the source is moving
away from the listener, its velocity v is positive,
but if it is moving toward the listener, then the v is negative.
The listener, in this case,
is always considered to be at rest (so v is really the total relative
velocity between them).
The speed of light c is always considered positive.
The listener receives a
frequency fL which would
be different from the frequency transmitted by the source fS.
This is calculated with
relativistic mechanics, by applying necessary the length contraction, and
obtains the relationship:
fL = sqrt [( c - v)/( c + v)] * fS
Red Shift & Blue Shift
A light source moving away from the listener (v is
positive) would provide an fL that is less than fS. In
the visible light spectrum, this causes a shift toward the red end of the
light spectrum, so it is called a redshift.
When the light source is
moving toward the listener (v is negative),
then fL is greater
than fS. In the visible
light spectrum, this causes a shift toward the high-frequency end of the light
spectrum.
For some reason, violet got
the short end of the stick and such frequency shift is actually called a blue shift.
Obviously, in the area of the
electromagnetic spectrum outside of the visible light spectrum, these shifts
might not actually be toward red and blue.
If you're in the infrared, for
example, you're ironically shifting away from red
when you experience a "redshift."
Applications
Police use this property in
the radar boxes they use to track speed. Radio waves are transmitted
out, collide with a vehicle, and bounce back.
The speed of the vehicle
(which acts as the source of the reflected wave) determines the change in
frequency, which can be detected with the box.
(Similar applications can be
used to measure wind velocities in the atmosphere, which is the "Doppler
radar" of which meteorologists are so fond.)
This Doppler shift is also
used to track satellites. By observing how the frequency changes, you can
determine the velocity relative to your location, which allows ground-based
tracking to analyze the movement of objects in space.
In astronomy, these shifts
prove helpful. When observing a system with two stars, you can tell which is
moving toward you and which away by analyzing how the frequencies change.
Even more significantly,
evidence from the analysis of light from distant galaxies shows that the light
experiences a redshift. These galaxies are moving away from the Earth.
In fact, the results of this
are a bit beyond the mere Doppler effect. This is actually a result of
spacetime itself expanding, as predicted by general relativity.
Extrapolations of this
evidence, along with other findings, support the "big bang" picture
of the origin of the universe.
Andrew
Zimmerman Jones
Introduction
Academic
researcher, educator, and writer with 23 years of experience in
physical sciences
Works
at Indiana Department of Education as senior assessment specialist in
mathematics
Co-author
of String Theory For Dummies
Member
of the National Association of Science Writers
Experience
Andrew
Zimmerman Jones is a former writer for ThoughtCo who contributed nearly 200
articles for more than 10 years. His topics ranged from the definition
of energy to vector mathematics. Andrew is a dedicated educator;
and he uses his background in the physical sciences, educational
assessment, writing, and communications to advance that mission.
Andrew
is co-author of String Theory For Dummies, which discusses the basic
concepts of this controversial approach. String theory tries
to explain certain phenomena that are not currently explainable under the
standard quantum physics model.
Since
2018, Andrew has worked at the Indiana Department of Education as a senior
assessment specialist in mathematics; prior to which he served as a senior
assessment editor at CTB/McGraw Hill for 10 years. In addition, Andrew was a
researcher at Indiana University's Cyclotron Facility. He is a member
of the National Association of Science Writers.
Education
Andrew
Zimmerman Jones has a Master of Science (M.S.) in Mathematics Education
from Indiana University–Purdue, Indianapolis, Ind.; and a Bachelor of Arts
(B.A.) in Physics from Wabash College, Crawfordsville, Ind.
Awards
and Publications
String Theory For Dummies (Wiley–For Dummies Series,
2009)
Graduated magna
cum laude (Wabash College, 1999)
Harold
Q. Fuller Prize in Physics (Wabash College, 1998)
ThoughtCo
and Dotdash
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