Videos
What produced the helium now present in the Sun’s atmosphere? In Jupiter’s atmosphere? In the Sun’s core?
What produced the helium now present in the atmosphere of the Sun, in Jupiter’s atmosphere and in the Sun’s core.
Answer to Problem 1RQ
The helium in the Sun’s atmosphere was produced by fusion of hydrogen to helium in the Sun’s core. Since planets were formed at the same time as the Sun, Jupiter’s atmosphere also contains Helium.
Explanation of Solution
Introduction:
The Solar Nebula theory for evolution of the Solar system rests on the following premises:
1. A rotating cloud of gas collects and flattens itself into a disc.
2. The disc becomes thinner with the Sun at the center.
3.The disc clears after the gas coalesces into planets.
The Big Bang theory presumes the Universe to have formed out of an explosion. In a few moments after Big Bang, the intense temperature, resulted in formation of protons, neutrons and electrons. The protons fused together due the prevalent high temperature to produce Helium.
A cloud of gas mainly containing Hydrogen and Helium stars to collect and rotate about an axis. The cloud of gas flattens itself into a thin disc with the Sun at the center. The gas in the disc coalesces into planets.
The Solar system was formed at the same time as the Sun. Hence the core of the Sun contains Helium formed by fusion of protons. The atmosphere of the Sun contains the same elements present in the Sun’s core. The planets were formed at the same time as the Sun. Hence Jupiter’s atmosphere also contains Helium. Helium is retained in the atmosphere of Jupiter due to its great gravitational force.
Conclusion:
Thus, the helium in the Sun’s atmosphere was produced by fusion of hydrogen to helium in the Sun’s core and since planets were formed at the same time as the Sun, Jupiter’s atmosphere also contains Helium.
Want to see more full solutions like this?
Chapter 15 Solutions
Horizons: Exploring the Universe - With MindTap
- How can i solve this if n1 (refractive index of gas) and n2 (refractive index of plastic) is not known. And the brewsters angle isn't knownarrow_forward2. Consider the situation described in problem 1 where light emerges horizontally from ground level. Take k = 0.0020 m' and no = 1.0001 and find at which horizontal distance, x, the ray reaches a height of y = 1.5 m.arrow_forward2-3. Consider the situation of the reflection of a pulse at the interface of two string described in the previous problem. In addition to the net disturbances being equal at the junction, the slope of the net disturbances must also be equal at the junction at all times. Given that p1 = 4.0 g/m, H2 = 9.0 g/m and Aj = 0.50 cm find 2. A, (Answer: -0.10 cm) and 3. Ay. (Answer: 0.40 cm)please I need to show all work step by step problems 2 and 3arrow_forward
- look at answer show all work step by steparrow_forwardLook at the answer and please show all work step by steparrow_forward3. As a woman, who's eyes are h = 1.5 m above the ground, looks down the road sees a tree with height H = 9.0 m. Below the tree is what appears to be a reflection of the tree. The observation of this apparent reflection gives the illusion of water on the roadway. This effect is commonly called a mirage. Use the results of questions 1 and 2 and the principle of ray reversibility to analyze the diagram below. Assume that light leaving the top of the tree bends toward the horizontal until it just grazes ground level. After that, the ray bends upward eventually reaching the woman's eyes. The woman interprets this incoming light as if it came from an image of the tree. Determine the size, H', of the image. (Answer 8.8 m) please show all work step by steparrow_forward
Foundations of Astronomy (MindTap Course List)PhysicsISBN:9781337399920Author:Michael A. Seeds, Dana BackmanPublisher:Cengage Learning
Horizons: Exploring the Universe (MindTap Course ...PhysicsISBN:9781305960961Author:Michael A. Seeds, Dana BackmanPublisher:Cengage Learning
Stars and Galaxies (MindTap Course List)PhysicsISBN:9781337399944Author:Michael A. SeedsPublisher:Cengage Learning
AstronomyPhysicsISBN:9781938168284Author:Andrew Fraknoi; David Morrison; Sidney C. WolffPublisher:OpenStax