SMALL STARS HAVE A MASS of up to about one and a half times that of
the Sun. They begin to form when a region of higher density in a nebulae condenses into a huge globule of gas and dust
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| Small stars |
that contracts under its own gravity. Within a globule, regions of condensing matter heat up and begin to glow, forming
Protostars. If a protostar contains enough matter, the central temperature reaches
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| Protostar(At the center) |
about 8 million
oC. At this temperature, nuclear reactions (in which hydrogen fuses to form helium) can start. This process releases energy, which prevents
the star from contracting further and also causes it to shine; it is now a
main sequence star. A star of about 1 solar mass remains on the main sequence for about 10 billion years, until much of the hydrogen in the star's core has been converted into helium. The helium core then contracts, and nuclear reactions continue in a shell around the core. The core becomes hot enough for helium to fuse to form carbon, while the outer layers of the star expand and cool. The expanding star is known as
Red Giant. When the helium in the core runs out,
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| Structure of main sequence star |
the outer layers of the star may be blown away as an expanding gas shell called a
Planetary Nebulae (explained it in my previous blog Part-4). The remaining core (about 80% of the original star) is now in its final stages. It becomes a
White Dwarf Star that gradually cools and dims.
When it finally stops shining altogether, the dead star will become a
Black Dwarf.
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| Black Dwarf |
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| Life cycle of Small Stars |
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