Concept explainers
The definition of horizon and flatness problem and the steps adopted to resolve them by the idea of inflation.
Explanation of Solution
Introduction:
Horizon problem originates due to the observation of constant temperature of (CMBR) cosmic microwave background
Flatness problem is the cosmological problem, which describes that the density of the universe is close to the critical value of density, which is impossible and leads to the flatness problem.
Horizon problem originates due to the observation of the nearly constant temperature of the cosmic microwave background radiation. After the big bang, the radiation emitted is continuously traveling in the observable universe. Two points in the universe which are at very distant locations to each other, that is nearly a million light-years, cannot have the temperature of cosmic microwave background radiation similar to each other. This is because the radiation from the big bang cannot reach such a distant point in the space, so it leads to the horizon problem.
On the other hand, flatness problem arises due to the observation of density of the universe to be nearly equal to the critical density, which is considered impossible. After the billion light-years from the big bang, still the geometry of the universe resembles that of flat surface which is considered a problem in cosmology.
The solution to the horizon and the flatness problem is cosmic inflation which states that the universe is expanding after the big bang at an exponential rate in the initial inflationary period resulting in the isotropic nature of the universe observed today. This theory also states the fact that during the inflationary period the energy and mass were equally distributed resulting in constant temperature observed in the universe.
Conclusion:
Therefore, the cosmic inflation theory gives the solution to Horizon and Flatness problems.
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Chapter 26 Solutions
Universe: Stars And Galaxies
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- If a galaxy is 500 Mly away from us, how fast do we expect it to be moving and in what direction?arrow_forwardLarge redshifts move the positions of spectral lines to longer wavelengths and change what can be observed from the ground. For example, suppose a quasar has a redshift of =4.1 . At what wavelength would you make observations in order to detect its Lyman line of hydrogen, which has a laboratory or rest wavelength of 121.6 nm? Would this line be observable with a ground-based telescope in a quasar with zero redshift? Would it be observable from the ground in a quasar with a redshift of =4.1 ?arrow_forwardIf the cosmic microwave background radiation (CMBR) is the remnant of the Big Bang’s ?reball, we expect to see hot and cold regions in it. What are two causes of these wrinkles in the CMBR? Are the observed temperature variations greater or less than originally expected?arrow_forward
- (a) What Hubble constant corresponds to an approximate age of the universe of 1010 y? To get an approximate value, assume the expansion rate is constant and calculate the speed at which two galaxies must move apart to be separated by 1 Mly (present average galactic separation) in a time of 1010 y. (b) Similarly, what Hubble constant corresponds to a universe approximately 21010years old?arrow_forwardOn average, how far away are galaxies mat are moving away from us at 2.0% of the speed of light?arrow_forward20. Gravitational lensing can be used to detect which component of the Universe? a. Dark Matter. b. Photons. c. Dark Energy. d. Electrons.arrow_forward
- The farthest objects in our Universe discovered by modern astronomers are so distant that light emitted by them takes billions of years to reach the Earth. These objects (known as quasars) have many puzzling features, which have not yet been satisfactorily explained. What is the distance in km of a quasar from which light takes 3.0 billion years to reach us ?arrow_forwardDark Matter and Closure• Discuss the existence of dark matter.• Explain neutrino oscillations and their consequences.arrow_forwardThe first picture is some background information need help answering the first question about the escape velocity from the andromeda Galaxyarrow_forward
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