5.7 Doppler effect for light

University physics volume 3 Page 1 / 2

By the end of this section, you will be able to:

Explain the origin of the shift in frequency and wavelength of the observed wavelength when observer and source moved toward or away from each other
Derive an expression for the relativistic Doppler shift
Apply the Doppler shift equations to real-world examples

As discussed in the chapter on sound, if a source of sound and a listener are moving farther apart, the listener encounters fewer cycles of a wave in each second, and therefore lower frequency, than if their separation remains constant. For the same reason, the listener detects a higher frequency if the source and listener are getting closer. The resulting Doppler shift in detected frequency occurs for any form of wave. For sound waves, however, the equations for the Doppler shift differ markedly depending on whether it is the source, the observer, or the air, which is moving. Light requires no medium, and the Doppler shift for light traveling in vacuum depends only on the relative speed of the observer and source.

The relativistic doppler effect

Suppose an observer in S sees light from a source in $S'$ moving away at velocity v ( [link] ). The wavelength of the light could be measured within $S'$ —for example, by using a mirror to set up standing waves and measuring the distance between nodes. These distances are proper lengths with $S'$ as their rest frame, and change by a factor $\sqrt{1 - v^{2} / c^{2}}$ when measured in the observer’s frame S , where the ruler measuring the wavelength in $S'$ is seen as moving.

In figure a: An observer is shown at the origin of a stationary frame S. The S prime frame is moving to the right with velocity v relative to frame S. A source at the origin of S prime is shown emitting a sinusoidal wave that propagates to the left. In figure b, six cycles of the wave are shown as seen by the observer and as seen by the source. The wavelength of the wave seen by the observer is longer than that of the wave seen by the source. The width of the six cycles as seen by the source is labeled as c delta t. The extra length to the end of the six cycles as seen by the observer is labeled as v delta t. — (a) When a light wave is emitted by a source fixed in the moving inertial frame $S',$ the observer in S sees the wavelength measured in $S' .$ to be shorter by a factor $\sqrt{1 - v^{2} / c^{2}} .$ (b) Because the observer sees the source moving away within S , the wave pattern reaching the observer in S is also stretched by the factor $(c Δ t + v Δ t) / (c Δ t) = 1 + v / c .$

If the source were stationary in S , the observer would see a length $c Δ t$ of the wave pattern in time $Δ t .$ But because of the motion of $S'$ relative to S , considered solely within S , the observer sees the wave pattern, and therefore the wavelength, stretched out by a factor of

\frac{c Δ t_{period} + v Δ t_{period}}{c Δ t_{period}} = 1 + \frac{v}{c}

as illustrated in (b) of [link] . The overall increase from both effects gives

λ_{obs} = λ_{src} (1 + \frac{v}{c}) \sqrt{\frac{1}{1 - \frac{v^{2}}{c^{2}}}} = λ_{src} (1 + \frac{v}{c}) \sqrt{\frac{1}{(1 + \frac{v}{c}) (1 - \frac{v}{c})}} = λ_{src} \sqrt{\frac{(1 + \frac{v}{c})}{(1 - \frac{v}{c})}}

where $λ_{src}$ is the wavelength of the light seen by the source in $S'$ and $λ_{obs}$ is the wavelength that the observer detects within S .

Red shifts and blue shifts

The observed wavelength $λ_{obs}$ of electromagnetic radiation is longer (called a “red shift”) than that emitted by the source when the source moves away from the observer. Similarly, the wavelength is shorter (called a “blue shift”) when the source moves toward the observer. The amount of change is determined by

λ_{obs} = λ_{s} \sqrt{\frac{1 + \frac{v}{c}}{1 - \frac{v}{c}}}

where $λ_{s}$ is the wavelength in the frame of reference of the source, and v is the relative velocity of the two frames S and $S' .$ The velocity v is positive for motion away from an observer and negative for motion toward an observer. In terms of source frequency and observed frequency, this equation can be written as

Questions & Answers

what is force

Afework Reply

The different examples for collision

Afework

What is polarization and there are type

Muhammed Reply

Polarization is the process of transforming unpolarized light into polarized light. types of polarization 1. linear polarization. 2. circular polarization. 3. elliptical polarization.

Eze

Describe what you would see when looking at a body whose temperature is increased from 1000 K to 1,000,000 K

Aishwarya Reply

how is tan ninety minus an angle equals to cot an angle?

Niicommey Reply

please I don't understand all about this things going on here

Jeremiah Reply

What is torque?

Matthew Reply

In physics and mechanics, torque is the rotational equivalent of linear force. It is also referred to as the moment, moment of force, rotational force or turning effect, depending on the field of study.

Teka

Torque refers to the rotational force. i.e Torque = Force × radius.

Arun

Torque is the rotational equivalent of force . Specifically, it is a force exerted at a distance from an object's axis of rotation. In the same way that a force applied to an object will cause it to move linearly, a torque applied to an object will cause it to rotate around a pivot point.

Teka

Torque is the rotational equivalence of force . So, a net torque will cause an object to rotate with an angular acceleration. Because all rotational motions have an axis of rotation, a torque must be defined about a rotational axis. A torque is a force applied to a point on an object about the axis

Teka

When a missle is shot from one spaceship towards another, it leaves the first at 0.950c and approaches the other at 0.750c. what is the relative velocity of the two shipd

Marifel Reply

how to convert:m^3/s^2 all divided by kg to cm^3/s^2

Thibaza Reply

Is there any proof of existence of luminiferious aether ?

Zero Reply

mass conversion of 58.73kg =mg

Proactive Reply

is Space time fabric real

Godawari Reply

What's the relationship between the work function and the cut off frequency in the diagram above?

frankline Reply

due to the upthrust weight of the object varise with force in which the body fall into the water pendincular with the reflection of light with it

Gift

n=I/r

Gift

can someone explain what is going on here

falanga

so some pretty easy physics questions bring em

falanga

what is meant by fluctuated

Olasukanmi Reply

If n=cv then how v=cn? and if n=c/v then how v=cn?

Natanim

convert feet to metre

Mbah Reply

what is electrolysis

Mbah

Electrolysis is the chemical decomposition of electrolyte either in molten state or solution to conduct electricity

Ayomide

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Ayesha Reply

can someone help explain why v2/c2 is =1/2 Using The Lorentz Transformation For Time Spacecraft S′ is on its way to Alpha Centauri when Spacecraft S passes it at relative speed c /2. The captain of S′ sends a radio signal that lasts 1.2 s according to that ship’s clock. Use the Lorentz transformati

Jennifer

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Source: OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4

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