Suns, including our own sun, work through a process called nuclear fusion. Nuclear fusion is the process by which lighter atomic nuclei combine to form heavier nuclei, releasing a tremendous amount of energy in the process. This energy is what powers the sun and allows it to emit light and heat.
Here's a simplified overview of how nuclear fusion works in stars like the sun:
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Hydrogen Nuclei: The primary fuel for nuclear fusion in stars is hydrogen. In the core of the sun, temperatures and pressures are incredibly high, causing hydrogen nuclei (protons) to move at very high speeds.
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Collision and Fusion: Due to the high speeds and collisions, hydrogen nuclei overcome their mutual electrostatic repulsion and get close enough for the strong nuclear force to bind them together. This results in the formation of a heavier nucleus, helium-4 (two protons and two neutrons).
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Release of Energy: The mass of the resulting helium nucleus is slightly less than the combined mass of the original hydrogen nuclei. This "missing" mass is converted into energy according to Einstein's famous equation, E=mc². This energy is released in the form of gamma-ray photons.
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Heat and Light: These high-energy photons are absorbed and re-emitted multiple times by other particles in the sun's core before eventually reaching the surface. As they reach the surface, they are released as visible light and other forms of electromagnetic radiation (including heat).
This continuous process of nuclear fusion in the sun's core releases an enormous amount of energy, which radiates out into space in the form of light and heat. This energy provides the sunlight and warmth that sustain life on Earth.
It's important to note that the sun is primarily composed of hydrogen, and its nuclear fusion process is responsible for maintaining its stability and energy output. This process has been ongoing for billions of years and is expected to continue for billions more before the sun eventually exhausts its hydrogen fuel.