Ten billion light years isn't longer than the size is the visible universe, so I think you've made a mistake there.bahamagreen said:Per Wikipedia (Outer Space) referencing Davies, P. C. W. (1977), "...the mean free path of a photon in intergalactic space is about 10E23 km, or 10 billion light years."
Per Lawrence Krauss (1999), it is longer than the size of the visible universe.
What is the current thinking about this?
The mistake is that 10 billion light years is far too short. This is probably because the mean free path was not well-measured until WMAP in the early 2000's, so the 1977 estimate is naturally quite far off.bahamagreen said:How am I making a mistake by asking about the discrepancy between to values of the photon MFP in space?
kimbyd said:...around 95% of photons between us and the CMB never scattered...
It means that roughly 10% of the signal we receive is polarized at any point on the sky.bahamagreen said:"...the CMB is linearly polarized at the 10% level due to Thomson scattering of photons off free electrons in the surface of last scattering. CMB polarization was first detected by DASI from the South Pole in 2002 and has since been observed by many other experiments."
https://www.cfa.harvard.edu/~cbischoff/cmb/
Does "polarized at the 10% level" mean only 10% of the photons are polarized or does it mean that all the photons are polarized 10%?
The polarization is only measured in the aggregate. The total signal at each point on the sky is polarized by some amount.bahamagreen said:Does "10% of the signal" mean 10% of the photons are polarized or all the photons are polarized 10% or the average polarization is 10%?
The photon mean free path is the average distance that a photon travels before interacting with matter. In other words, it is the average distance between two consecutive collisions of a photon with particles in a medium.
The CMB black body assumption states that the cosmic microwave background radiation (CMB) has a black body spectrum, meaning that it follows a specific distribution of photon energies. The photon mean free path is important in this assumption because it determines the distance over which photons can travel without being scattered or absorbed by matter. This allows us to understand how the CMB radiation has been affected by the universe's expansion and the evolution of matter since the Big Bang.
The photon mean free path is affected by the density and composition of the medium through which the photons are traveling. Higher densities and heavier elements lead to shorter mean free paths, as there is a greater chance of photon interactions. In addition, the energy of the photons also plays a role, as higher energy photons have shorter mean free paths due to their increased likelihood of interactions.
The photon mean free path can be measured through observations of the CMB radiation. By studying the intensity and temperature fluctuations of the CMB, scientists can infer the mean free path of the photons. This information can also be used to validate the CMB black body assumption and provide insights into the composition and evolution of the universe.
The photon mean free path is a crucial parameter in understanding the evolution of the universe. It allows us to study the interactions between photons and matter, which provide valuable insights into the early stages of the universe's formation. By studying the CMB radiation and its mean free path, scientists can also gain a better understanding of the properties of dark matter and dark energy, two mysterious components that make up the majority of our universe.