Stellar classification (astrophysics): Difference between revisions

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Stars are classed by various properties. A common classification is surface temperature. Beginning with early spectral schema in the 19th century ranking stars from A to P, the spectral classification, called “Morgan-Keenan spectral classification” <ref>Note: based on the work of Annie Cannon and other astronomers from the Harvard College Observatory</ref><ref>[http://www.sdsc.edu/ScienceWomen/cannon.html Annie Jump Cannon] 1883-1941</ref> now ranks stars in seven main types: O, B, A, F, G, K, M.<ref>A popular mnemonic for this is '''O'''h '''B'''e '''A''' '''F'''ine '''G'''irl, '''K'''iss '''M'''e</ref> Each spectral classification is further divided into  tenths. Our sun, Sol is a G2.
Stars are classed by various properties. A common classification is surface temperature. Beginning with early spectral schema in the 19th century ranking stars from A to P, the spectral classification, called “Morgan-Keenan spectral classification” <ref>Note: based on the work of Annie Cannon and other astronomers from the Harvard College Observatory</ref><ref>[http://www.sdsc.edu/ScienceWomen/cannon.html Annie Jump Cannon] 1883-1941</ref> now ranks stars in seven main types: O, B, A, F, G, K, M.<ref>A popular mnemonic for this is '''O'''h '''B'''e '''A''' '''F'''ine '''G'''irl, '''K'''iss '''M'''e</ref> Each spectral classification is further divided into  tenths. Our sun, Sol is a G2.
==History==
In 1801,<ref>Note: Sources give varying dates between 1801 and 1807</ref> William Hyde Wollaston (1766-1828)<ref>[http://chem.ch.huji.ac.il/history/wollaston.html William Hyde Wollaston] Hebrew University of Jerusalem, Institute of Chemistry; [http://www.acmi.net.au/AIC/WOLLASTON_BIO.html William Hyde Wollaston : 1766 – 1828] Dean P. Currier. Australian Centre for the moving image; [http://www.zeiss.com/c12567a100537ab9/Contents-Frame/056301e9396f8be0c125695a002468e6 William Hyde Wollaston] Carl Zeiss AG; [http://micro.magnet.fsu.edu/optics/timeline/people/wollaston.html William Hyde Wollaston] Michael W. Davidson, Florida State University; [http://www.hao.ucar.edu/Public/education/Timeline.D.html History of Solar Physics - A Time Line of Great Moments 1800-1999] National Center for Atmospheric Research & The UCAR Office Programs; [http://www.hao.ucar.edu/Public/education/bios/wollaston.html William Hyde Wollaston (1766-1828)] High Altitude Observatory, National Center for Atmospheric Research & The UCAR Office Programs </ref> noted absorption lines in the solar spectrum. The solar spectrum was not a continuous band of colour and included a series of dark lines. Wollaston perceived this as a possible boundary between colours.
Joseph von Fraunhofer (1787-1826)<ref>[http://www.hao.ucar.edu/Public/education/bios/fraunhofer.html Joseph von Fraunhofer] High Altitude Observatory, National Center for Atmospheric Research & The UCAR Office Programs; [http://www.newadvent.org/cathen/06250a.htm Joseph von Fraunhofer] New Advent Catholic Encyclopedia; [http://www.fraunhofer.de/fhg/Images/joseph_tcm6-5806.pdf  Joseph von Fraunhofer] Fraunhofer-Gesellschaft</ref> in 1814, studied this phenomena and concluded that the dark bands represented specific wavelengths.
In 1863, Sir William Huggins (1824-1910)<ref>[http://seds.org/messier/xtra/Bios/huggins.html William Huggins (February 7, 1824 - May 12, 1910)] Messier Catalog, Students for the Exploration and Development of Space</ref> laid the final piece of the puzzle in place and compared these solar spectrums with other stars and terrestrial substances. In this way it was demonstrated that the dark bands, now known as Fraunhofer Lines,<ref>[http://laserstars.org/spectra/Fraunhofer.html Identificatio of spectral lines-History of Fraunhofer lines] University of Ottawa; [http://www.genesismission.org/educate/scimodule/SSWPrOptPDFs/5HereComesLight/FranhoferLines-ST-PO.pdf The Fraunhofer Lines] Jet Propulsion Lab, California Institute of Technology, NASA</ref> are the absorption lines for chemical elements present in the stars. Specific chemicals present in the outer layers of a star absorb specific wavelengths creating the dark lines. This also showed that the stars are made of the same substances here on Earth.
While this work provided for the foundation of the field of spectroscopy it also provided a tool for astrophysics and astronomy. These distinctive spectral lines which provide information about the chemical composition of the stars have become the basis for their classification.


==Classification system==
==Classification system==

Revision as of 21:44, 26 October 2007

Stars are classed by various properties. A common classification is surface temperature. Beginning with early spectral schema in the 19th century ranking stars from A to P, the spectral classification, called “Morgan-Keenan spectral classification” [1][2] now ranks stars in seven main types: O, B, A, F, G, K, M.[3] Each spectral classification is further divided into tenths. Our sun, Sol is a G2.

History

In 1801,[4] William Hyde Wollaston (1766-1828)[5] noted absorption lines in the solar spectrum. The solar spectrum was not a continuous band of colour and included a series of dark lines. Wollaston perceived this as a possible boundary between colours.

Joseph von Fraunhofer (1787-1826)[6] in 1814, studied this phenomena and concluded that the dark bands represented specific wavelengths.

In 1863, Sir William Huggins (1824-1910)[7] laid the final piece of the puzzle in place and compared these solar spectrums with other stars and terrestrial substances. In this way it was demonstrated that the dark bands, now known as Fraunhofer Lines,[8] are the absorption lines for chemical elements present in the stars. Specific chemicals present in the outer layers of a star absorb specific wavelengths creating the dark lines. This also showed that the stars are made of the same substances here on Earth.

While this work provided for the foundation of the field of spectroscopy it also provided a tool for astrophysics and astronomy. These distinctive spectral lines which provide information about the chemical composition of the stars have become the basis for their classification.

Classification system

The stars are ranked from hottest to coldest:

Class Temperature Conventional vs Apparent color

[9]

Characteristics

[10]

Mass [11] Radius [12] Luminosity [13] Hydrogen lines % of all MSSs[14][15]
O 30,000–60,000 K blue/blue Ionized He & metals;

weak H

60 M 15 R 1,400,000 L Weak ~0.00003%
B 10,000–30,000 K blue white/blue white to white Neutral He, ionized metals, stronger H 18 M 7 R 20,000 L Medium 0.13%
A 7,500–10,000 K white/white Balmer H dominant, singly-ionized metals 3.1 M 2.1 R 80 L Strong 0.6%
F 6,000–7,500 K yellowish white/white H weaker, neutral & singly-ionized metals 1.7 M 1.3 R 6 L Medium 3%
G 5,000–6,000 K yellow/yellow Singly ionized Ca, H weaker, neutral metals 1.1 M 1.1 R 1.2 L Weak 8%
K 3,500–5,000 K orange/yellow orange Neutral Metals, molecular bands begin to appear 0.8 M 0.9 R 0.4 L Very weak 13%
M 2,000–3,500 K red/orange red Ti oxide molecular lines; neutral metals 0.3 M 0.4 R 0.04 L Very weak >78%

[16]

References

  1. Note: based on the work of Annie Cannon and other astronomers from the Harvard College Observatory
  2. Annie Jump Cannon 1883-1941
  3. A popular mnemonic for this is Oh Be A Fine Girl, Kiss Me
  4. Note: Sources give varying dates between 1801 and 1807
  5. William Hyde Wollaston Hebrew University of Jerusalem, Institute of Chemistry; William Hyde Wollaston : 1766 – 1828 Dean P. Currier. Australian Centre for the moving image; William Hyde Wollaston Carl Zeiss AG; William Hyde Wollaston Michael W. Davidson, Florida State University; History of Solar Physics - A Time Line of Great Moments 1800-1999 National Center for Atmospheric Research & The UCAR Office Programs; William Hyde Wollaston (1766-1828) High Altitude Observatory, National Center for Atmospheric Research & The UCAR Office Programs
  6. Joseph von Fraunhofer High Altitude Observatory, National Center for Atmospheric Research & The UCAR Office Programs; Joseph von Fraunhofer New Advent Catholic Encyclopedia; Joseph von Fraunhofer Fraunhofer-Gesellschaft
  7. William Huggins (February 7, 1824 - May 12, 1910) Messier Catalog, Students for the Exploration and Development of Space
  8. Identificatio of spectral lines-History of Fraunhofer lines University of Ottawa; The Fraunhofer Lines Jet Propulsion Lab, California Institute of Technology, NASA
  9. The Colour of Stars. Australia Telescope Outreach and Education (December 21 2004). Retrieved on 2007-10-26. — Explains the reason for the difference in color perception.
  10. The Hertzasprung-Russell diagram (subsection The Harvard spectral sequence). University of Tennessee, Dept of Physics and Astronomy (unknown). Retrieved on 2007-10-26. — Details various aspects of stellar classification.
  11. NASA glossary Solar Mass. Earth's sun is one solar mass. Equal to about 2 X 10E30 kg or about 333,000 time the mass of the earth
  12. Solar Radius. Earth's sun is the standard with one solar radius equal to about 6.960 X 10E8 km. This is about twice the distance of the earth from the moon, 110 times the radius of earth, and 0.004652 AU (astronomical unit), the average distance of the earth from the sun. Solar Radius University of Oregon. The Corona Spartan 201. NASA
  13. Solar Luminosity. The standard is earth's sun equal to one solar luminosity. The luminosity of the sun is about 3.827 X 10E26 watts or 3.827 X 10E33 ergs
  14. MSS = Main Sequence Star
  15. LeDrew, G.; The Real Starry Sky, Journal of the Royal Astronomical Society of Canada, Vol. 95, No. 1 (whole No. 686, February 2001), pp. 32–33
  16. Star classification

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Wolf 359 (star)

Proxima Centauri (star)


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