Tanelorn said:Chronos, you mentioned that supernovae are only observable up to ~ z=2 yet the CMBR is of course observable at z=1100. How is that the photons from a high intensity event such as a supernovae are attenuated so much, yet the photons from the 3000K (or is it 5000K) BB last scattering hydrogen gas (ie. much lower energy) can still reach us? Is it related to different interstelar medium attenuations for different photon frequencies?
Chronos said:The most recent efforts to measure curvature have included supernova, CMB anisotropy, and giant void studies. Supernova make good 'standard candles' because they are phenomenally bright and believed to have uniform peak luminosity. Unfortunately, even supernova are difficult to detect beyond about z=2, which is a pretty small slice of a universe that is observable out to about z=1100 [CMB]. The cosmic microwave background (CMB) is known to be highly sensitive to spatial curvature of the universe. By measuring small angle fluctuations in the temperature of the CMS, curvature near the surface of last scattering can be estimated. Giant void studies attempt to model supernovae observations without resorting to dark energy. Some of these models are compatible with the small angle CMB measurements, but, the voids must be peculiarly deep and empty, or the universe is positively curved. Older methods have included galactic surveys, relying on the size of the largest galaxies or their numerial density in any given volume of space. The error margins of such these methods are large for a number of reasons. All of the measurement methods tried to date have proven inconclusive. All we can say at this point is they are not inconsistent with a flat Universe.
Thank you. That's what I have been looking for.Chronos said:The most recent efforts to measure curvature have included supernova, CMB anisotropy, and giant void studies. Supernova make good 'standard candles' because they are phenomenally bright and believed to have uniform peak luminosity. Unfortunately, even supernova are difficult to detect beyond about z=2, which is a pretty small slice of a universe that is observable out to about z=1100 [CMB]. The cosmic microwave background (CMB) is known to be highly sensitive to spatial curvature of the universe. By measuring small angle fluctuations in the temperature of the CMS, curvature near the surface of last scattering can be estimated. Giant void studies attempt to model supernovae observations without resorting to dark energy. Some of these models are compatible with the small angle CMB measurements, but, the voids must be peculiarly deep and empty, or the universe is positively curved. Older methods have included galactic surveys, relying on the size of the largest galaxies or their numerial density in any given volume of space. The error margins of such these methods are large for a number of reasons. All of the measurement methods tried to date have proven inconclusive. All we can say at this point is they are not inconsistent with a flat Universe.
minio said:Thank you. I am trying to get insight how curvature is measured, simply because I do not like flat universe idea. So I want to know how it is measured and what assumptions are made to be able make up my mind.
salvestrom said:Imagine trying to observe the CMB if it only existed as a single point in the sky the size of a z=2 supernova.
The curvature of the universe is measured using a combination of observations and mathematical models. Observations of the cosmic microwave background radiation, the distribution of galaxies, and the rate of expansion of the universe are used to determine the curvature of space. This information is then plugged into mathematical equations, such as the Friedmann equation, to calculate the exact curvature of the universe.
Scientists use a variety of tools to measure the curvature of the universe, including telescopes and satellites that observe the cosmic microwave background radiation, which is a remnant of the early universe. They also use computer simulations and mathematical models to analyze and interpret the data collected from these observations.
According to current theories, the curvature of the universe is constant and does not change over time. However, there are some theories, such as the cyclic model of the universe, that suggest the curvature may change during different phases of the universe's existence. Further research and observations are needed to fully understand the concept of changing curvature in the universe.
The curvature of the universe is directly related to its overall shape. A positively curved universe, also known as a closed universe, has a spherical shape. A negatively curved universe, also called an open universe, has a saddle-like shape. A flat universe has zero curvature and is believed to have a shape similar to a sheet of paper.
While most scientists agree on the general concept of measuring the curvature of the universe, there are still ongoing debates and controversies surrounding the exact value and interpretation of the data. Some theories, such as inflationary cosmology, have proposed different values for the curvature, leading to ongoing discussions and research in the scientific community.