The temperature of the Sun's core is estimated to be around 15 million degrees Kelvin (27 million degrees Fahrenheit). This extreme heat is generated by nuclear fusion reactions that convert hydrogen into helium.
No, all stars aren't suns. A sun is a star that is at the center of a solar system. Planets rotate around the sun. Planets don't rotate around a normal star. A star can be found anywhere around the universe. That's not the case with planets. Planets have to be in a solar system and a sun has to be in the center. If this is the case with a star, then that star can be called a sun.
Iron is not formed in the Sun through nuclear fusion. Iron is the element with the highest nuclear binding energy per nucleon, making it less energetically favorable for fusion reactions to produce iron in the Sun. Iron is typically formed in the later stages of a massive star's life during a supernova explosion.
The nuclear reactions in the Sun primarily involve fusion of hydrogen nuclei to form helium, releasing energy in the process. In a nuclear reactor, the reactions typically involve fission of heavy nuclei like uranium or plutonium, releasing energy through splitting these nuclei. The conditions and mechanisms governing the reactions in the Sun and in a nuclear reactor are different due to the vastly varying scales and environments of the two systems.
The majority of the Sun's radiation output comes from nuclear fusion reactions in its core, where hydrogen atoms are fused into helium. This process releases energy in the form of electromagnetic radiation, including visible light, ultraviolet light, and infrared radiation.
Hydrogen (into Helium).
nuclear fusion reactions at the core of sun
Yes, at temperatures around 15.6 million degrees Celsius in the Sun's core, nuclear fusion reactions can occur. These reactions involve the fusion of hydrogen nuclei into helium nuclei, releasing immense amounts of energy in the form of light and heat.
Fusion reactions decrease the overall number of particles in the core, causing the core to shrink, converting gravitational potential energy into thermal energy, and increasing the rate of fusion.
thermonuclear fusion and hydrogen becoming helium... :)
nuclear fusion energy
Chemical reactions
Nuclear fusion.
It is fusion of hydrogen to form helium
Energy is created by nuclear fusion
Helium
Sun's energy is primarily the result of nuclear fusion reactions occurring in its core. These reactions fuse hydrogen atoms together to form helium, releasing a large amount of energy in the process. This energy is what powers the Sun and provides light and heat to our solar system.