Star Formation

> Star Formation

Stellar evolution begins with a giant molecular cloud (GMC), also known as a stellar nursery. Most of the 'empty' space inside a galaxy actually contains around 0.1 to 1 particle per cm³, but inside a GMC, the typical density is a few million particles per cm³. A GMC contains 100,000 to 10,000,000 times as much mass as our Sun by virtue of its size: 50 to 300 light years across.

As a GMC orbits the galaxy, one of several events might occur to cause its gravitational collapse. GMCs may collide with each other, or pass through dense regions of spiral arms. A nearby supernova explosion can also be a trigger, sending shocked matter into the GMC at very high speeds. Finally, galactic collisions can trigger massive bursts of star formation as the gas clouds in each galaxy are compressed and agitated by the collision.

A collapsing GMC fragments as it collapses, breaking into smaller and smaller chunks. Fragments with masses of less than about 50 solar masses are able to form into stars. In these fragments, the gas is heated as it collapses due to the release of gravitational potential energy, and the cloud becomes a protostar as it forms into a spherical rotating object.

Great Nebula in Orion

A star begins life as a large, relatively cool mass of gas, part of a nebula such as the Great Nebula in Orion

This initial stage of stellar existence is almost invariably hidden away deep inside dense clouds of gas and dust. Often, these star-forming cocoons can be seen in silhouette against bright emission from surrounding gas, and are then known as Bok globules.

Very small protostars never reach temperatures high enough for nuclear fusion to begin; these are brown dwarfs of less than 0.1 solar mass. They die away slowly, cooling gradually over hundreds of billions of years. The central temperature in more massive protostars, however, will eventually reach 10 megakelvins, at which point hydrogen begins to fuse into helium. The star begins to shine. The onset of nuclear fusion sets up a hydrostatic equilibrium in which energy released by the core prevents further gravitational collapse. The star then exists in a stable state.

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Maturity

Energy making during normal life

Maturity

New stars come in a variety of sizes and colors. They range in spectral type from hot and blue to cool and red, and in mass from less than 0.5 to more than 20 solar masses. The brightness and color of a star depend on its surface temperature, which in turn depends on its mass.

As gravity in a nebula causes the gas to contract, its temperature rises, eventually becoming high enough to trigger a nuclear reaction in its atoms. The shining of a main-sequence star is caused by the steady output of vast amounts of energy from the fusion of hydrogen nuclei to form helium. The main-sequence phase of a medium-sized star is believed to last as long as 10 billion years.

A new star will fall at a specific point on the main sequence of the Hertzsprung-Russell diagram. Small, cool red dwarfs burn hydrogen slowly and may remain on the main sequence for hundreds of billions of years, while massive hot supergiants will leave the main sequence after just a few million years. A mid-sized star like the Sun will remain on the main sequence for about 10 billion years. Once a star expends most of the hydrogen in its core, it moves off the main sequence.

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Energy making during normal life

During the major part of their lives, most stars on the Main Sequence will create their energy by the process of hydrogen fusion - the process of fusing two hydrogen atoms to create one helium atom. Energy is created because a helium atom weighs slightly less than the two hydrogen atoms, and the excess mass is converted into energy, as related by Einstein's famous equation E=m*c². Our sun is currently in this stage of converting hydrogen to helium.

In the picture below, two protons join together to form a deuterium nucleus, which is also known as "heavy water." A positron and a neutrino are released as by-products. The deuterium nucleus is bombarded by another proton, creating a helium-3 nucleus. The by-product of this is a photon in the form of a gamma ray (a very high-energy form of light). Then, the helium-3 nucleus in bombarded by another helium-3 nucleus, creating a normal helium-4 nucleus. The by-product of this are two protons, which are free to start the whole process over again. The positron will be destroyed and form another gamma ray; the energy from this in the form of gamma rays is radiated out of sun's core.

Since our sun is currently in this stage, the numbers here are for it alone, although since it is like most other stars, the are representative of how all stars work. Each second, the sun converts 500 million metric tons of hydrogen to helium. In turn, every second 5 million metric tons of excess material is converted into energy. This means that every year, 157,680,000,000,000 metric tons are converted into energy. The material from one second energy is about 1x1027 (one octillion thousand) watts of energy. On Earth, we receive about 2/1,000,000,000 (two billionths) of that energy, or about 2x1018 (two quintillion) watts. This is enough energy to power 100 average light bulbs for about 5 million years -- longer than humans have been standing upright.

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