- Cosmology Tutorial
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- The Expanding Universe
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- Matter Dominated Universe
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- The Dark Energy
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- Velocity Dispersion Measurements of Galaxies
- Hubble & Density Parameter
- Age of The Universe
- Angular Diameter Distance
- Luminosity Distance
- Type 1A Supernovae
- Cosmic Microwave Background
- CMB - Temperature at Decoupling
- Anisotropy of CMB Radiation & Cobe
- Modelling the CMB Anisotropies
- Horizon Length at the Surface of Last Scattering
- Extrasolar Planet Detection
- Radial Velocity Method
- Transit Method
- Exoplanet Properties
- Cosmology Useful Resources
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- Cosmology - Discussion
Horizon Length at the Surface of Last Scattering
Horizon length is the distance travelled by light photons from ‘The Big Bang’ to ‘The Recombination Era’. The 1st peak of the angular spectrum is at θ = 1◦ (l = 180), which is a very special length scale.
The proper distance between two points is given by −
$$r_p = \int_{0}^{t}cdt$$
When we take the time frame of t = 0 to t = trec, then
$$r_H = \int_{0}^{t_{rec}}cdt$$
Where $r_H$ is the proper horizon distance.
Now, we know that −
$$\dot{a} = \frac{\mathrm{d} a}{\mathrm{d} t}$$
$$dt = \frac{da}{\dot{a}}$$
When t = 0, a = 0.
Then $t = t_{rec}, a = a_0 / (1 + z_{rec})$.
Hence, we can write,
$$r_H(z_{rec})=\int_{0}^{a_{rec}} c\frac{da}{aH}$$
$$H(a_{rec}) = H(z_{rec}) = H_0\sqrt{\Omega_{m,0}}a^{-3/2}$$
During the Recombination period universe was matter dominated. i.e., Ωrad << Ωmatter. Therefore, the term radiation is dropped.
$$r_H(z_{rec}) = \frac{c}{H_0\sqrt{\Omega_{m,0}}}\int_{0}^{a_{rec}} \frac{da}{a^{-1/2}}$$
$$r_H(z_{rec}) = \frac{2c}{3H_0\sqrt{\Omega_{m,0}}}\frac{1}{(1+z_{rec})^{3/2}}$$
$$\theta_H(rec) = \frac{r_H(z_{rec})}{d_A(z_{rec})}$$
Which is equal to 0.5 degrees, if we put all the known values in the equation.
The Electromagnetic radiation is opaque from the surface of last scattering. Any two points ‘not’ lying within the horizon of each other need not have the same properties. So, it will give different temperature values.
We can get two points on this surface which did not intersect with each other, which means at one point the universe expanded faster than the speed of light which is the inflationary model for expansion.
Points to Remember
The horizon length is the distance travelled by light photons from ‘The Big Bang’ to ‘The Recombination Era’.
During the Recombination period, the universe was matter dominated.
Electromagnetic radiation is opaque from the surface of last scattering.
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