Redshift/blueshift and time dilation

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SUMMARY

This discussion centers on the relationship between redshift/blueshift and time dilation in the context of special relativity. Participants explore whether knowing the redshift factor, such as a factor of 4, allows for the calculation of time dilation for a moving object relative to a stationary observer. Key formulas are provided, including the Doppler factor (k=e^θ) and the time-dilation factor (γ=coshθ). The conversation emphasizes that to accurately determine time dilation, one must consider the relative speed, gravitational potential difference, and the expansion of space-time.

PREREQUISITES
  • Understanding of special relativity concepts
  • Familiarity with the Doppler Effect
  • Knowledge of gravitational potential and its effects on light
  • Basic grasp of space-time expansion principles
NEXT STEPS
  • Study the Doppler Effect in detail, focusing on its mathematical implications
  • Research the concept of gravitational time dilation and its calculations
  • Examine the expansion of space-time and its effects on light propagation
  • Read "Spacetime Physics" by Taylor and Wheeler for a deeper understanding of rapidity and time dilation
USEFUL FOR

Astronomers, physicists, and students of relativity who seek to understand the implications of redshift and blueshift on time dilation and the broader effects of space-time dynamics.

Quantumgravity
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Would it be possible to calculate the time dilation of an object if you only knew how redshifted or blueshifted the light coming from the object was? For example, if you knew the wavelength was redshifted by a factor of 4, or by a certain number of meters, could you determine the time dilation of the object relative to you, the stationary observer?
 
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Quantumgravity said:
Would it be possible to calculate the time dilation of an object if you only knew how redshifted or blueshifted the light coming from the object was? For example, if you knew the wavelength was redshifted by a factor of 4, or by a certain number of meters, could you determine the time dilation of the object relative to you, the stationary observer?
Those who teach relativity with human face start with the radar echo, and continue, in a logical order, with the adition law of velocities, the Doppler Effect and optical aberration. I recomend
Asher Peres, "Relativistic telemetry," Am.J.Phys. 55, 516 (1987)
Peter Kenny, "Time dilation in special relativity: an alternative derivation,"
Physics Education 41(4), 334-336 (2006).
I find the last paper very transparent.
Being intertested in the field, I will answer to any further question you may have,concerning the subject, which could clarify my own bewilderment! Have a look please at the thread I started "Radar echo and clock synchronization".
 
With rapidities, the answer is easily demonstrated.

The Doppler factor (not to be confused with the Doppler shift) is k=e^\theta, and the time-dilation factor \gamma=\cosh\theta=\frac{1}{2}(e^\theta+e^{-\theta}).
So, \gamma=\frac{1}{2}(k+k^{-1}). Similarly, it's easy to write down the velocity using v=c \tanh\theta.
 
Thanks, rothenstein. Your thread was enlightening.

Robphy, thank you for the formula. I will need to do some research to fully understand it however.
 
I enjoyed the reading very much. I understand the math a bit better now.
 
Quantumgravity said:
Would it be possible to calculate the time dilation of an object if you only knew how redshifted or blueshifted the light coming from the object was? For example, if you knew the wavelength was redshifted by a factor of 4, or by a certain number of meters, could you determine the time dilation of the object relative to you, the stationary observer?
When we measure a source that emits red or blueshifted light we have to take the following three factors into account:

1. The relative speed between the emmitted and absorbed source.
2. The gravitational potential difference between the emmitted and absorbed source.
3. The expansion of space-time.

So if we only know the actual red- or blueshift then we cannot conclusively determine the amount of time dilation.
 
MeJennifer said:
When we measure a source that emits red or blueshifted light we have to take the following three factors into account:

1. The relative speed between the emmitted and absorbed source.
2. The gravitational potential difference between the emmitted and absorbed source.
3. The expansion of space-time.

So if we only know the actual red- or blueshift then we cannot conclusively determine the amount of time dilation.
Explain please what do you mean by expansion of space-time and what is its connection with the discussed problem. Thanks.
 
I think MeJennifer means that if the object we were talking about was something like a galaxy, and the space between us and the galaxy was expanding, it would stretch the wavelenth of light along with it. I read about that in a Scientific American article. I'm not sure how the photons are able to 'stick' to the fabric of space-time, but somehow they do, and if space-time stretches, so does light.
 

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