Is the Shapiro time delay effect accepted in science ?

In summary, a test known as the Shapiro time delay has been proposed and used to confirm predictions of General Relativity, but it is not responsible for the redshift observed in galaxies. This delay involves a change in travel time, but does not affect wavelengths. It has been proposed for use in measuring the Hubble expansion rate, but is not related to cosmological redshift caused by expansion. It is considered a classical test of General Relativity and is widely accepted by mainstream science.
  • #1
guacamolewar
2
0
If it is : I would love someone to explain to me how it affect the redshift of galaxies.

If it is not : I will toss it in the pseudoscience box and not think about it again


Thank you

Guacamolewarrior
 
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  • #2
guacamolewar, Welcome to Physics Forums!

I am not sure if the Shapiro time delay applies to the redshift of galaxies. But, it sure does apply to radar signals here in our solar system. Here is an excerpt from the Wikipedia page describing tests (proofs) of General Relativity. His prediction has proven to be correct; do not throw it into the "pseudoscience box".

“Irwin I. Shapiro proposed another test, beyond the classical tests, which could be performed within the solar system. It is sometimes called the fourth "classical" test of general relativity. He predicted a relativistic time delay (Shapiro delay) in the round-trip travel time for radar signals reflecting off other planets.[26] The mere curvature of the path of a photon passing near the Sun is too small to have an observable delaying effect (when the round-trip time is compared to the time taken if the photon had followed a straight path), but general relativity predicts a time delay which becomes progressively larger when the photon passes nearer to the Sun due to the time dilation in the gravitational potential of the sun. Observing radar reflections from Mercury and Venus just before and after it will be eclipsed by the Sun gives agreement with general relativity theory at the 5% level.[27] More recently, the Cassini probe has undertaken a similar experiment which gave agreement with general relativity at the 0.002% level. Very Long Baseline Interferometry has measured velocity-dependent (gravitomagnetic) corrections to the Shapiro time delay in the field of moving Jupiter [28][29] and Saturn.”

http://en.wikipedia.org/wiki/Tests_of_general_relativity
 
  • #3
Thank you.


Could this effect be responsible for the redshift observed in galaxies?
 
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  • #4
I could find no reference that says the Shapiro Time Delay effect is responsible for the redshift of galaxies. However, your question is interesting because of, from the above reference, this: "general relativity predicts a time delay which becomes progressively larger when the photon passes nearer to the Sun due to the time dilation in the gravitational potential of the sun."

So, when photons emitted by a galaxy climb out of the gravitational potential well on their way toward us, wouldn't they experience this time dilation? If so, would it be equivalent to a redshift? Or is that simply "gravitational redshift"? I defer to others more educated in this area.
 
  • #5
Bobbywhy said:
So, when photons emitted by a galaxy climb out of the gravitational potential well on their way toward us, wouldn't they experience this time dilation? If so, would it be equivalent to a redshift? Or is that simply "gravitational redshift"? I defer to others more educated in this area.

Er, wouldn't a photon experiencing time dilation undermine the entire point of time dilation? Or does it actually explain why a photon can't exceed it's measured speed??
 
  • #6
guacamolewar said:
Could this effect be responsible for the redshift observed in galaxies?

Don't see how. Shapiro delay changes the travel time, but it doesn't change wavelengths.
 
  • #7
twofish-quant said:
Don't see how. Shapiro delay changes the travel time, but it doesn't change wavelengths.
I don't quite understand this. It kinda has to, at least during the transition from a lower time delay to a higher time delay, and vice versa. Though I would definitely accept that it doesn't cause any change in wavelength along a path that has no change in the time delay.

But in response to the OP, no, the Shapiro time delay can't realistically have anything at all to do with the redshift of galaxies, because if it were then you'd end up with dramatically different redshifts just because one galaxy happened to be behind another, and since as many galaxies are going to be transitioning into such an alignment as transitioning out of that alignment, there would be exactly as much redshift as blueshift. None of this remotely matches what we observe.

However, the Shapiro time delay is useful in cosmology, and attempts have been made to use this time delay to, for example, measure the Hubble expansion rate. The basic setup is that they observe a lensed object which has two or more images, an object which has some sort of variation (quasars, for example, vary a lot, and a lot of lensed objects are quasars). In general, we expect that different paths that the photons take will have different travel times. So we might see one image brighten just a few moments before another image, and the difference in travel times gives us information about the curvature of space-time around that lens.
 
  • #8
The shapiro delay is basically a consequence of gravitational redshift applied to radar signaling. Accordingly it has little to do with cosmological redshift that is due to expansion.
It certainly involves deviation from expected radar frequencies in the absence of gravitational time dilation.
It is totally accepted by mainstream and considered the 4th of the classical test of GR.
 
  • #9
Guacamolewar is a sockpuppet of a banned crackpot.
 

1. What is the Shapiro time delay effect?

The Shapiro time delay effect is a phenomenon in which the gravitational field of a massive object, such as a star, bends the path of light passing near it. This results in a delay in the time it takes for the light to reach an observer, as predicted by Einstein's theory of general relativity.

2. How was the Shapiro time delay effect first discovered?

The Shapiro time delay effect was first discovered in 1964 by physicists Irwin Shapiro and John E. Campbell. They observed that radio waves passing near the planet Mercury were delayed by a small amount as they traveled to Earth, confirming Einstein's prediction.

3. Is the Shapiro time delay effect widely accepted in the scientific community?

Yes, the Shapiro time delay effect is widely accepted in the scientific community. It has been confirmed through numerous experiments and observations, and is a key component of Einstein's theory of general relativity.

4. What are the implications of the Shapiro time delay effect?

The Shapiro time delay effect has important implications for our understanding of gravity and the behavior of light in the presence of massive objects. It also has practical applications, such as in the accurate navigation of spacecraft.

5. Are there any ongoing studies or experiments related to the Shapiro time delay effect?

Yes, there are ongoing studies and experiments related to the Shapiro time delay effect, particularly in the field of gravitational waves. Scientists are also using this effect to study the properties of distant objects, such as black holes, and to test the limits of Einstein's theory of general relativity.

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