Star
A star is a very large ball of bright, glowing, hot matter in space. That matter is called plasma. Stars are held together by gravity. They emit light because they are very hot. The Sun is an example of a star. It is at the center of the solar system.
The amount of material in a star (its mass) is so huge that a nuclear reaction called nuclear fusion goes on inside it. This reaction changes hydrogen to helium and gives off heat. The light and heat created by nuclear fusion makes stars very hot. It also makes bigger chemical elements. In the Sun (but not all stars) the change which takes place is the production of helium, with small amounts of heavier elements.
Stars have a lot of hydrogen. Fusion makes a lot of energy. The energy produced by stars moves (radiates) away from them. Much of the energy leaves as light, and the rest leaves as other kinds of electromagnetic radiation.
When a star like the Sun gets old, it will expand in size and become a red giant star. That will happen in about 5 billion years.
Earth's Sun
The star nearest to Earth is the Sun. The energy from the Sun supports almost all life on Earth by providing light for plants. Plants turn the light into energy in a process called photosynthesis.[1] The energy from the Sun also causes weather and humidity on Earth.
We can see other stars in the night sky when the Sun goes down. Like the Sun, they are made mostly of hydrogen and a little bit of helium plus other elements. Astronomers compare those other stars to the Sun. Their mass is measured in solar masses (Mʘ). A solar mass is the mass of the Sun. A small star may be about 0.2 Mʘ, a medium one may be about the Sun's mass (1 Mʘ), and a large star may be about 10 Mʘ.
Planets
The Earth and other planets move around (orbit) the Sun. The Sun and all things that orbit it are called the Solar System. Many other stars have planets orbiting them, and those planets are called exoplanets. Our Sun would look like a star in the sky to someone on an exoplanet, but you would not see the Earth from one because it would be too far away.
Numbers, distances
Proxima Centauri is the closest star to the Sun. It is 39.9 trillion kilometres, equal to 4.2 light years, away. This means that light from Proxima Centauri takes 4.2 years to reach Earth.
Astronomers think there is a very large number of stars in the Universe. The observable Universe contains more than 2 trillion (1012) galaxies[2] and, overall, as many as an estimated 1×1024 stars[3][4] (more stars than all the grains of sand on planet Earth).[5] That is, 1,000,000,000,000,000,000,000,000 stars, which is many times more than the few hundred billion stars in our galaxy, the Milky Way.
Most stars are very old. They are usually thought to be between 1 billion and 10 billion years old. The oldest stars are 13.7 billion years old. That is as old as the Universe. Some young stars are only a few million years old.
Stars are different sizes. The smallest stars are neutron stars, which are actually dead stars. They are no bigger than a human city. A neutron star has a large amount of mass in a very small space. A neutron star has a mass of at least 1.4 Mʘ.
Hypergiant stars are the largest stars in the Universe. They have a diameter up to 1,600 times bigger than the Sun's. If the Sun was a hypergiant star, it would reach out to as far as Jupiter.
The star Betelgeuse is a red supergiant star about 640[6] times the Sun's diameter. Although these stars are very large, they also have low density.
Some stars look brighter than other stars. This difference is measured in terms of apparent magnitude. There are two reasons why stars have different apparent magnitude. If a star is very close to us, it will appear much brighter. This is just like a candle. A candle that is close to us appears brighter. The other reason a star can appear brighter is that it is hotter than another cooler star.
Stars give off light but also give off a solar wind and neutrinos. These are very small particles of matter.
Stars are made of mass and mass makes gravity. Gravity makes planets orbit stars. This is why the Earth orbits the Sun. The gravity of two stars can make them go around each other. Stars that orbit each other are called binary stars. Scientists think there are many binary stars. There are even groups of three or more stars that orbit each other. Proxima Centauri is a small star that orbits other stars.
Stars are not spread evenly across all of space. Instead, they are grouped into galaxies. A galaxy contains hundreds of billions of stars.
History of seeing stars
Stars have been important to people all over the world for all of history. Stars have also been part of religious practices. Long ago, people believed that stars could never die.
Astronomers organized stars into groups called constellations. They used the constellations to help them see the motion of the planets and to guess the position of the Sun.[7] The motion of the Sun and other stars was used to make calendars. The calendars were used by farmers to decide when to plant crops and when to harvest them.[9]
The life of stars
Stars are made in nebulae. These are areas that have more gas than normal space. The gas in a nebula is pulled together by gravity. The Orion nebula is an example of a place where gas is coming together to form stars.
Stars spend most of their lives combining (fusing) hydrogen with hydrogen to make energy. When hydrogen is fused it makes helium and it makes a lot of energy. To fuse hydrogen into helium it must be very hot and the pressure must be very high. Fusion happens at the center of stars, called "the core".
The smallest stars are called red dwarfs. Red dwarfs fuse their hydrogen slowly and live for more than 100 billion years, so they live longer than any other star. At the end of their lives, they become dimmer and dimmer. Red dwarfs do not explode.
When very heavy stars die, they explode. This explosion is called a supernova. When a supernova happens in a nebula, the explosion pushes the gas in the nebula together. This makes the gas in the nebula very dense (thick). Gravity and exploding stars both help to bring the gas together to make new stars in nebulas.
Most stars use up the hydrogen at their core. When they do, their core becomes smaller and hotter. It becomes so hot that it pushes away the outer part of the star. The outer part expands and it makes a red giant star. Astrophysicists think that in about 5 billion years, the Sun will be a red giant. Our Sun will be so large it will "eat" the Earth. After our Sun stops using hydrogen to make energy, it will use helium in its very hot core. It will be hotter than when it was fusing hydrogen. Heavy stars will also make elements heavier than helium. As a star makes heavier and heavier elements, it makes less and less energy. Iron is a heavy element made in heavy stars.
Our star is an average star. Average stars will push away their outer gases. The gas it pushes away makes a cloud called a planetary nebula. The core part of the star will remain. It will be a ball as big as the Earth and called a white dwarf. It will fade into a black dwarf over a very long time.
Later in large stars (~ 10 Mʘ), heavier elements are made by fusion. Finally the star makes a supernova explosion. Most things happen in the universe so slowly we do not notice. But supernova explosions happen in only 100 seconds. When a supernova explodes its flash is as bright as a 100 billion stars. The dying star is so bright it can be seen during the day. Supernova means "new star" because people used to think it was the beginning of a new star. Today we know that a supernova is the death of an old star. The gas of the star is pushed away by the explosion. It forms a giant cloud of gas called a planetary nebula. The crab nebula is a good example. All that remains is a neutron star. If the star was very heavy (~ 25 Mʘ), the star will make a black hole. Gravity in a black hole is extremely strong. It is so strong that even light cannot escape from a black hole.
The heaviest elements are made in the explosion of a supernova. After billions of years of floating in space, the gas and dust come together to make new stars and new planets. Much of the gas and dust in space comes from supernovae. Our Sun, the Earth, and all living things are made from star dust.
Colors
Astronomers have known for centuries that stars have different colors. When looking at an electromagnetic spectrum, ultraviolet waves are the shortest, and infrared are the longest.[10] The visible spectrum has wavelengths between these two extremes.
Modern instruments can measure very precisely the color of a star. This allows astronomers to determine that star's temperature, because a hotter star's black-body radiation has shorter wavelengths. The hottest stars are blue and azure, then white, then yellow, and the coolest are red.[11] Below is a list of the coolest stars.
Name | Temperature (K) | Radius (Solar radii) |
---|---|---|
V688 Monocerotis | 1670 | 1347 |
CWISE J124909.08+362116.0 | 1715 | 0.08 |
S Cassiopeiae | 1800 | 930 |
RW Leonis Minoris | 1800 | 1028.27 |
LL Pegasi | 1800 | 1074 |
V384 Persei | 1820 | 937 |
2MASS J07464256+2000321 A | 1822 | 0.089 |
T Draconis | 1850 | 1200 |
HIP 113330 | 1859 | 649.091 |
V346 Puppis | 1875 | 1025 |
HD 110813 | 1916 | 843.811 |
2MASS J0523-1403 | 1939 | 0.086 |
S Aurigae | 1940 | 957 |
V1426 Cygni | 1975 | 216.1 |
Knowing the color and absolute magnitude, astronomers can place the star on the Hertzsprung-Russell diagram, and estimate its habitable zone and other facts about it.
For example, our Sun is yellow-white, and the Earth is the perfect distance away for life. If our Sun was a hotter, blue star, however, Earth would have to be much farther away or else it would be too hot to have water and sustain life.
Star Media
Infrared image from NASA's Spitzer Space Telescope showing hundreds of thousands of stars in the Milky Way galaxy
An example of a Hertzsprung–Russell diagram for a set of stars that includes the Sun (center) (see Classification)
Betelgeuse as seen by ALMA. This is the first time that ALMA has observed the surface of a star and resulted in the highest-resolution image of Betelgeuse available.
Artist's impression of the Sirius system, a white dwarf star in orbit around an A-type main-sequence star
References
- ↑ Simon A. 2001 (9 October 2001). The real science behind the X-Files: microbes, meteorites, and mutants. Simon & Schuster. pp. 25–27. ISBN 0684856182.
- ↑ Fountain, Henry (17 October 2016). "Two Trillion Galaxies, at the Very Least". The New York Times. https://www.nytimes.com/2016/10/18/science/two-trillion-galaxies-at-the-very-least.html. Retrieved 17 October 2016.
- ↑ Staff (2019). "How Many Stars Are There In The Universe?". European Space Agency. Retrieved 21 September 2019.
- ↑ Marov, Mikhail Ya. (2015). "The Structure of the Universe". The Fundamentals of Modern Astrophysics. pp. 279–294. doi:10.1007/978-1-4614-8730-2_10. ISBN 978-1-4614-8729-6.
- ↑ Mackie, Glen (1 February 2002). "To see the Universe in a Grain of Taranaki Sand". Centre for Astrophysics and Supercomputing. Retrieved 28 January 2017.
- ↑ Mittag, M.; Schröder, K.-P.; Perdelwitz, V.; Jack, D.; Schmitt, J. H. M. M. (2023-01-01). "Chromospheric activity and photospheric variation of α Ori during the great dimming event in 2020". Astronomy & Astrophysics. 669: A9. doi:10.1051/0004-6361/202244924. ISSN 0004-6361.
- ↑ 7.0 7.1 Forbes, George (1909). History of Astronomy (Free e-book from Project Gutenberg). London: Watts & Co. ISBN 1153627744.
- ↑ Hevelius, Johannis (1690). Firmamentum Sobiescianum, sive Uranographia. Gdansk.
- ↑ Tøndering, Claus. "Other ancient calendars". WebExhibits. Archived from the original on 2019-11-21. Retrieved 2006-12-10.
- ↑ "The Electromagnetic Spectrum". Andy Darvill's Science Site. Retrieved 2016-06-06.
- ↑ "Star Colors Explained". One Minute Astronomer. December 23, 2008. Archived from the original on 2016-03-27. Retrieved 2016-06-06.
Other websites
- Media related to Star at Wikimedia Commons
- Green, Paul J (2005). "Star". World Book Online Reference Center. World Book, Inc. Archived from the original on 2005-05-08. Retrieved 2010-08-20.
- Kaler, James. "Portraits of Stars and their Constellations". University of Illinois. Archived from the original on 2008-12-17. Retrieved 2010-08-20.
- "Query star by identifier, coordinates or reference code". SIMBAD. Centre de Données astronomiques de Strasbourg. Retrieved 2010-08-20.
- "How To Decipher Classification Codes". Astronomical Society of South Australia. Retrieved 2010-08-20.
- "Live Star Chart". Dobsonian Telescope Community. Archived from the original on 2012-12-04. Retrieved 2010-08-20. View the stars above your location
- Prialnick, Dina; Wood, Kenneth; Bjorkman, Jon; Whitney, Barbara; Wolff, Michael; Gray, David; Mihalas, Dimitri (2001). "Stars: Stellar Atmospheres, Structure, & Evolution". University of St. Andrews. Archived from the original on 2021-02-11. Retrieved 2010-08-20.
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