Parsec

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Parsec
stellar parallax motion from annual parallax
Unit information
Unit system astronomical units
Unit of length
Symbol pc
Unit conversions
1 pc in... is equal to...
   SI units    3.0857×1016 m
   imperial & US units    1.9174×1013 mi
   other astronomical    2.0626×105 AU
      units    3.26156 ly
For other uses, see Parsec (disambiguation).

A parsec (symbol: pc) is an astronomical unit of distance derived by the theoretical annual parallax (or heliocentric parallax) of one arc second, and is found as the inverse of that measured parallax. In astronomical terms, parallaxes are the apparent measured difference in the position of a star as seen from Earth and another hypothetical observer at the Sun. As the distance is the inverse of the parallax, the smaller the measured parallax the larger the celestial object's distance.

One parsec equals about 3.26 light-years (30.9 trillion kilometres or 19.2 trillion miles). All known stars lie more than one parsec away, with Proxima Centauri showing the largest parallax of 0.7687 arcsec, making the distance 1.3009 parsecs (4.243 light years).[1] Most of the visible stars in the nighttime sky lie within 500 parsecs of the Sun.

The parsec was introduced to make quick calculations of astronomical distances without the need for more complicated conversions, i.e. knowing the true speed of light to calculate light years. Parsec is named from the abbreviation of the parallax of one arcsecond, and was likely first suggested by British astronomer Herbert Hall Turner in 1913.[2]

Usage of parsecs is preferred in astronomy and astrophysics, though popular science texts commonly use light-years, probably because it is much easier to understand the amount of time it takes light to travel from the source. Multiples of parsecs are commonly used for scales in the universe, including parsecs for the visible stars, kiloparsecs for galactic objects and megaparsecs for nearby and more distant galaxies.

History and derivation

See also: Stellar parallax
A parsec is the distance from the Sun to an astronomical object which has a parallax angle of one arcsecond. (the diagram is not to scale (1 pc ≈ 206264.81 au)).

The parsec is equal to the length of the adjacent side of an imaginary right triangle in space. The two dimensions on which this triangle is based are the subtended angle of 1 arcsecond, and the opposite side that is defined as 1 astronomical unit, being the average Earth-Sun distance. From both values, along with the rules of trigonometry, the unit length of the adjacent side (the parsec) can be derived.

One of the oldest methods for astronomers to calculate the distance to a star was to record the difference in angle between two measurements of the position of the star in the sky. The first measurement was taken from the Earth on one side of the Sun, and the second was taken half a year later when the Earth was on the opposite side of the Sun. The distance between the two positions of the Earth when the two measurements were taken was known to be twice the distance between the Earth and the Sun. The difference in angle between the two measurements was known to be twice the parallax angle, which is formed by lines from the Sun and Earth to the star at the vertex. Then the distance to the star could be calculated using trigonometry.[3] The first successful direct measurements of an object at interstellar distances were undertaken by German astronomer Friedrich Wilhelm Bessel in 1838, who used this approach to calculate the three and a half parsec distance of 61 Cygni.[4]

The parallax of a star is taken to be half of the angular distance that a star appears to move relative to the celestial sphere as Earth orbits the Sun. Equivalently, it is the subtended angle, from that star's perspective, of the semi-major axis of Earth's orbit. The star, the Sun and the Earth form the corners of an imaginary right triangle in space: the right angle is the corner at the Sun, and the corner at the star is the parallax angle. The length of the opposite side to the parallax angle is the distance from the Earth to the Sun (defined as 1 astronomical unit (AU)), and the length of the adjacent side gives the distance from the sun to the star. Therefore, given a measurement of the parallax angle, along with the rules of trigonometry, the distance from the Sun to the star can be found. A parsec is defined as the length of the adjacent side of this right triangle in space when the parallax angle is 1 arcsecond.

The use of the parsec as a unit of distance follows naturally from Bessel's method, since distance in parsecs can be computed simply as the reciprocal of the parallax angle in arcseconds (i. e., if the parallax angle is 1 arcsecond, the object is 1 pc from the Sun; If the parallax angle is 0.5 arcsecond, the object is 2 pc away; etc.). No trigonometric functions are required in this relationship because the very small angles involved mean that the approximate solution of the skinny triangle can be applied.

Though it may have been used before, the term parsec was first mentioned in an astronomical publication in 1913. Astronomer Royal Frank Watson Dyson expressed his concern for the need of a name for that unit of distance. He proposed the name astron, but mentioned that Carl Charlier had suggested siriometer and Herbert Hall Turner had proposed parsec.[5] It was Turner's proposal that stuck.

Calculating the value of a parsec

In the diagram above (not to scale), S represents the Sun, and E the Earth at one point in its orbit. Thus the distance ES is one astronomical unit (AU). The angle SDE is one arcsecond (13600 of a degree) so by definition D is a point in space at a distance of one parsec from the Sun. By trigonometry, the distance SD is

SD={\frac {{\mathrm {ES}}}{\tan 1^{{\prime \prime }}}}

Using the small-angle approximation, by which the sine (and, hence, the tangent) of an extremely small angle is essentially equal to the angle itself (in radians),

SD\approx {\frac {{\mathrm {ES}}}{1^{{\prime \prime }}}}={\frac {1\,{\mbox{AU}}}{({\tfrac {1}{60\times 60}}\times {\tfrac {\pi }{180}})}}={\frac {648\,000}{\pi }}\,{\mbox{AU}}\approx 206\,264.81{\mbox{ AU}}.

Since the astronomical unit is defined to be 149597870700 metres,[6] the following can be calculated.

1 parsec 206264.81 astronomical units
3.0856776×1016 metres
19.173512 trillion miles
3.2615638 light years

A corollary is that 1 parsec is also the distance from which a disc with a diameter of 1 AU must be viewed for it to have an angular diameter of 1 arcsecond (by placing the observer at D and a diameter of the disc on ES).

Usage and measurement

The parallax method is the fundamental calibration step for distance determination in astrophysics; however, the accuracy of ground-based telescope measurements of parallax angle is limited to about 0.01 arcsecond, and thus to stars no more than 100 pc distant.[7] This is because the Earth’s atmosphere limits the sharpness of a star's image.[8] Space-based telescopes are not limited by this effect and can accurately measure distances to objects beyond the limit of ground-based observations. Between 1989 and 1993, the Hipparcos satellite, launched by the European Space Agency (ESA), measured parallaxes for about 100000 stars with an astrometric precision of about 0.97 milliarcsecond, and obtained accurate measurements for stellar distances of stars up to 1000 pc away.[9][10]

As of November 2013, ESA's Gaia satellite, which is scheduled to launch in December 2013, is intended to measure one billion stellar distances to within 20 microarcseconds, producing errors of 10% in measurements as far as the Galactic Center, about 8000 pc away in the constellation of Sagittarius.[11]

Distances in parsecs

Distances less than a parsec

Distances expressed in fractions of a parsec usually involve objects within a single star system. So, for example:

  • One astronomical unit (au), the distance from the Sun to the Earth, is just under 5×106 parsecs.
  • The most distant space probe, Voyager 1, was 0.0006 parsec (0.002 light-years) from Earth as of May 2013. It took Voyager 35 years to cover that distance.
  • The Oort cloud is estimated to be approximately 0.6 parsec (2.0 light-years) in diameter
The jet erupting from the active galactic nucleus of M87 is thought to be 1.5 kiloparsecs (4890 light-years) long. (image from Hubble Space Telescope)

Parsecs and kiloparsecs

Distances expressed in parsecs (pc) include distances between nearby stars, such as those in the same spiral arm or globular cluster. A distance of 1000 parsecs (3262 light-years) is commonly denoted by the kiloparsec (kpc). Astronomers typically use kiloparsecs to express distances between parts of a galaxy, or within groups of galaxies. So, for example:

  • One parsec is approximately 3.26 light-years.
  • The nearest known star to the Earth, other than the Sun, Proxima Centauri, is 1.30 parsecs (4.24 light-years) away, by direct parallax measurement.
  • The distance to the open cluster Pleiades is 130 ± 10 pc (420 ± 32.6 light-years) from us, per Hipparcos parallax measurement.
  • The center of the Milky Way is more than 8 kiloparsecs (26000 ly) from the Earth, and the Milky Way is roughly 34 kpc (110000 ly) across.
  • The Andromeda Galaxy (M31) is ~780 kpc (~2.5 million light-years) away from the Earth.

Megaparsecs and gigaparsecs

A distance of one million parsecs (3.26 million light-years or 3.26 "Mly") is commonly denoted by the megaparsec (Mpc). Astronomers typically express the distances between neighbouring galaxies and galaxy clusters in megaparsecs.

Galactic distances are sometimes given in units of Mpc/h (as in "50/h Mpc"). h is a parameter in the range [0.5,0.75] reflecting the uncertainty in the value of the Hubble constant H for the rate of expansion of the universe: h = H / (100 km/s/Mpc). The Hubble constant becomes relevant when converting an observed redshift z into a distance d using the formula d ≈ (c / H) × z.[12]

One gigaparsec (Gpc) is one billion parsecs — one of the largest units of length commonly used. One gigaparsec is about 3.26 billion light-years (3.26 "Gly"), or roughly one fourteenth of the distance to the horizon of the observable universe (dictated by the cosmic background radiation). Astronomers typically use gigaparsecs to express the sizes of large-scale structures such as the size of, and distance to, the CfA2 Great Wall; the distances between galaxy clusters; and the distance to quasars.

For example:

Volume units

To determine the number of stars in the Milky Way Galaxy, volumes in cubic kiloparsecs[lower-alpha 1] (kpc3) are selected in various directions. All the stars in these volumes are counted and the total number of stars statistically determined. The number of globular clusters, dust clouds, and interstellar gas is determined in a similar fashion. To determine the number of galaxies in superclusters, volumes in cubic megaparsecs[lower-alpha 1] (Mpc3) are selected. All the galaxies in these volumes are classified and tallied. The total number of galaxies can then be determined statistically. The huge void in Boötes[15] is measured in cubic megaparsecs.

In cosmology, volumes of cubic gigaparsecs[lower-alpha 1] (Gpc3) are selected to determine the distribution of matter in the visible universe and to determine the number of galaxies and quasars. The Sun is alone in its cubic parsec,[lower-alpha 1] (pc3) but in globular clusters the stellar density per cubic parsec could be from 100 to 1000.

References

Explanatory notes

  1. 1.0 1.1 1.2 1.3
    1 pc3 2.938×1049 m3
    1 kpc3 2.938×1058 m3
    1 Mpc32.938×1067 m3
    1 Gpc32.938×1076 m3

Citations

  1. Benedict, G. F. et al. "Astrometric Stability and Precision of Fine Guidance Sensor #3: The Parallax and Proper Motion of Proxima Centauri" (PDF). Proceedings of the HST Calibration Workshop. pp. 380–384. Retrieved 2007-07-11. 
  2. Dyson, F. W., Stars, Distribution and drift of, The distribution in space of the stars in Carrington's Circumpolar Catalogue. In: Monthly Notices of the Royal Astronomical Society, Vol. 73, p. 334–342. March 1913.
    "There is a need for a name for this unit of distance. Mr. Charlier has suggested Siriometer ... Professor Turner suggests PARSEC, which may be taken as an abbreviated form of 'a distance corresponding to a parallax of one second.'"
  3. High Energy Astrophysics Science Archive Research Center (HEASARC). "Deriving the Parallax Formula". NASA's Imagine the Universe!. Astrophysics Science Division (ASD) at NASA's Goddard Space Flight Center. Retrieved 2011-11-26. 
  4. Bessel, FW, "Bestimmung der Entfernung des 61sten Sterns des Schwans" (1838) Astronomische Nachrichten, vol. 16, pp. 65–96.
  5. Dyson, F. W., "The distribution in space of the stars in Carrington's Circumpolar Catalogue" (1913) Monthly Notices of the Royal Astronomical Society, vol. 73, pp. 334–42, p. 342 fn..
  6. "RESOLUTION B2 on the re-definition of the astronomical unit of length", RESOLUTION B2, Beijing, Kina: International Astronomical Union, 31 August 2012, retrieved 10 September 2012, "The XXVIII General Assembly of International Astronomical Union recommends [adopted] that the astronomical unit be re-defined to be a conventional unit of length equal to exactly 149597870700 metres, in agreement with the value adopted in IAU 2009 Resolution B2" 
  7. Richard Pogge, Astronomy 162, Ohio State.
  8. jrank.org, Parallax Measurements
  9. "The Hipparcos Space Astrometry Mission". Retrieved 28 August 2007. 
  10. Catherine Turon, From Hipparchus to Hipparcos
  11. GAIA from ESA.
  12. "Galaxy structures: the large scale structure of the nearby universe". Retrieved May 22, 2007. 
  13. Mei, S. et al 2007, ApJ, 655, 144
  14. "Misconceptions about the Big Bang". Retrieved January 8, 2010. 
  15. Astrophysical Journal, Harvard

External links

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