I don't think there is any sort of fundamental limit. There may be practical limits, but no fundamental one.Lost in Space said:Does anyone know what the limit is for light from distant objects to be so redshifted that they become undetectable? Could there be a way in detecting objects beyond this barrier? Would any wavelength at all be detectable?
Lost in Space said:Does anyone know what the limit is for light from distant objects to be so redshifted that they become undetectable? Could there be a way in detecting objects beyond this barrier? Would any wavelength at all be detectable?
Chalnoth said:I don't think there is any sort of fundamental limit. There may be practical limits, but no fundamental one.
Cosmo Novice said:After an infinite amount of time the wavelength takes for a full propogation will become infinitely long and would therefore require an infinite amount of time to detect it.
I think this would be the practical limit - not really a limit but i think you get my meaning.
Lost in Space said:Interesting comments, thanks. Is there then a way of detecting extremely redshifted light wavelengths that could indicate the presence of objects beyond the visible universe, and would the means of observation need to be purely determined by and limited to time? Observations in the visible light spectrum might not be possible of highly redshifted objects but what about shorter wavelengths? Wouldn't they still be detectable, like redshifted x-rays and gamma rays? And, if what you say is true about a full propagation ultimately taking an infinite amount of time, does this in turn mean that there are an infinite amount of wavelengths?
Nah, because before the surface of last scattering that phinds points out, our universe was opaque. So we can see stuff that was emitted some 13.7 billion light years ago, no earlier.Lost in Space said:Interesting comments, thanks. Is there then a way of detecting extremely redshifted light wavelengths that could indicate the presence of objects beyond the visible universe, and would the means of observation need to be purely determined by and limited to time? Observations in the visible light spectrum might not be possible of highly redshifted objects but what about shorter wavelengths? Wouldn't they still be detectable, like redshifted x-rays and gamma rays? And, if what you say is true about a full propagation ultimately taking an infinite amount of time, does this in turn mean that there are an infinite amount of wavelengths?
Redshift is a phenomenon in which light from an object appears to have longer wavelengths, or is shifted towards the red end of the spectrum. This occurs when an object is moving away from the observer at high speeds. In astronomy, redshift is important because it provides valuable information about the distance and speed of objects in the universe.
Redshift is typically measured using a spectrometer, which separates light into its component wavelengths. The amount of redshift can be determined by comparing the observed wavelength of a known spectral line with its expected wavelength. This difference can then be used to calculate the object's redshift.
There are three main types of redshift: cosmological, gravitational, and Doppler. Cosmological redshift is caused by the expansion of the universe and is used to measure the distance of objects. Gravitational redshift occurs when light is shifted due to the gravitational field of an object. Doppler redshift is caused by the relative motion between an object and the observer, and is used to determine the speed of objects.
The limits of redshift refer to the maximum and minimum values that can be observed. The maximum redshift is determined by the speed of light and the expansion rate of the universe. This limit can provide information about the age and size of the universe. The minimum redshift is determined by the sensitivity of instruments and the distance of the object. Understanding these limits is important for accurately interpreting redshift data and making conclusions about the properties of objects in the universe.
Yes, redshift can be used to estimate the age of the universe. By measuring the redshift of objects at different distances and using the known speed of light, scientists can determine the rate at which the universe is expanding. This information can then be used to calculate the age of the universe, which is currently estimated to be around 13.8 billion years old.