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Due to gravity the clouds will start to shrink. In the core density and temperature will become high enough so that nuclear fusion can start. The gas cloud becomes a stable star. This is the present state of our Sun.
Around the Sun a disk of gas and dust is left, containing about 1% of the mass of the Sun. In the inner part of the disk it is warm enough so that molecules like water, ammonia and methane tend to stay as gases and not produce grains and clumps and so on. And because they stay in gas form the radiation pressure from the Sun and the solar wind will push them outwards.
Around the orbit of Jupiter it becomes cold enough for ice to form. The gaseous molecules can produce grains and lumps so there's a lot of this less dense material around to accrete into planets. Jupiter and Saturn grew large enough to pull in great quantities of hydrogen and helium from the solar nebula.
The inner planets accreted from grains containing heavier atoms like oxygen and aluminium and silicon as well as iron and nickel and so on.
Consequently inside the ice limit at 5 AU only small, dense planets have formed, while outside there is matter enough to form the gas giants.
At this stage we have a dozen of proto-planets and quite a lot of comet-like, icy, small stuff. The proto-planets swept space clean with their gravitation fields and the comets rained on them. This also helped in making their orbits more circular.
But it was still a period with big collisions. For instance there are clear indications that the Moon was formed after a collision of the proto-Earth with another big object.
Nowadays, what is left over are zones like the asteroid belt, where Jupiter's perturbing gravity inhibited the formation of another planet. And also the Oort cloud, the region outside the orbit of Neptune, where dwarf planets like Pluto and Eris make their long orbits
What else can I help you with?
How does a star work to produce light and energy?
Stars produce light and energy through a process called nuclear fusion. In the core of a star, hydrogen atoms combine to form helium, releasing a large amount of energy in the form of light and heat. This energy is what makes stars shine brightly in the sky.
What is the process by which stars produce energy and what factors contribute to this phenomenon?
Stars produce energy through the process of nuclear fusion, where hydrogen atoms combine to form helium, releasing a tremendous amount of energy in the form of light and heat. Factors that contribute to this phenomenon include the star's mass, temperature, and pressure, which create the conditions necessary for nuclear fusion to occur.
Is fusion an atomic process that is used to produce energy?
Fusion occurs when two atomic nuclei collide. The reaction that is produce by the collision can be used to provide energy. Fusion is the reaction that powers most active stars in the universe.
What do Hydrogen bombs and stars both produce energy with nuclear?
Both hydrogen bombs and stars produce energy through nuclear fusion reactions that convert hydrogen atoms into helium. This process releases a tremendous amount of energy in the form of light and heat.
What is the combining of two small nuclei to produce heat and one larger nuclei called?
Nuclear fusion is the process of combining two small nuclei to produce heat and one larger nucleus. This process releases a large amount of energy and is the same process that powers the sun and stars.
What is the process occurring in stars to produce energy?
Nuclear fusion
What energy does the sun and stars produce?
the energy sun and stars produce is fusion.
What does the energy of a star come from?
Nuclear fusion, or the heating-up and smashing together of hydrogen nuclei, is the process via which stars produce energy.
What process that create energy in stars?
The energy in stars is created when hydrogren plasma, under extreme pressure and temperature, fuses to make helium plasma. The difference in mass between hydrogren and helium is also a difference in binding energy, which is released during the ongoing fusion reaction.
What do hydrogen bombs ands stars both produce nuclear with?
The process of fusion, where hydrogen is fused into heavier elements, releasing energy in the process.
Stars produce energy by fusing hydrogen into what?
Stars produce energy by fusing hydrogen into helium through a process called nuclear fusion. This fusion reaction releases a tremendous amount of energy in the form of light and heat, which powers the star and allows it to shine.
How does a star work to produce light and energy?
Stars produce light and energy through a process called nuclear fusion. In the core of a star, hydrogen atoms combine to form helium, releasing a large amount of energy in the form of light and heat. This energy is what makes stars shine brightly in the sky.
During nuclear fusion what do stars produce?
In nuclear physics and nuclear chemistry, nuclear fusionis the process by which multiple like-charged atomic nuclei join together to form a heavier nucleus. It is accompanied by the release or absorption of energy.
What is the process by which stars produce energy and what factors contribute to this phenomenon?
Stars produce energy through the process of nuclear fusion, where hydrogen atoms combine to form helium, releasing a tremendous amount of energy in the form of light and heat. Factors that contribute to this phenomenon include the star's mass, temperature, and pressure, which create the conditions necessary for nuclear fusion to occur.
What do stars produce through fusion?
Stars produce energy through nuclear fusion, which involves the fusion of hydrogen atoms to form helium. This process releases a tremendous amount of energy in the form of light and heat, which is what makes stars so luminous.
How do hydrogen bombs and stars both produce nuclear energy?
Stars like our sun and hydrogen bombs produce energy through nuclear fusion.
Is fusion an atomic process that is used to produce energy?
Fusion occurs when two atomic nuclei collide. The reaction that is produce by the collision can be used to provide energy. Fusion is the reaction that powers most active stars in the universe.
