Distance measures (cosmology)

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Distance measures are used in physical cosmology to give a natural notion of the distance between two objects or events in the universe. They are often used to tie some observable quantity (such as the luminosity of a distant quasar, the redshift of a distant galaxy, or the angular size of the acoustic peaks in the CMB power spectrum) to another quantity that is not directly observable, but is more convenient for calculations (such as the comoving coordinates of the quasar, galaxy, etc). The distance measures discussed here all reduce to the naïve notion of Euclidean distance at low redshift.

In accord with our present understanding of cosmology, these measures are calculated within the context of general relativity, where the Friedmann-Robertson-Walker solution is used to describe the universe.

1 Types of Distance Measures
2 Comparison of Distance Measures
3 See also
4 References
5 External links

[edit] Types of Distance Measures

Angular diameter distance or proper motion distance. Angular Diameter Distance is a good indication (especially in a flat universe) of how near an astronomical object was to us when it emitted the light that we now see.
Luminosity distance.
Comoving distance. The distance between two points measured along a path defined at the present cosmological time.
Cosmological proper distance. The distance between two points measured along a path defined at a constant cosmological time. The cosmological proper distance should not be confused with the more general proper length or proper distance.
Light travel time or lookback time. This is how long ago light left an object of given redshift.
Light travel distance (LTD). The light travel time times the speed of light. For values above 2 billion light years, this value does not equal the comoving distance or the angular diameter distance anymore, because of the expansion of the universe. Also see misconceptions about the size of the visible universe.
Naive Hubble's law, taking z = H₀d/c, with H₀ today's Hubble constant, z the redshift of the object, c the speed of light, and d the "distance."

[edit] Comparison of Distance Measures

A comparison of cosmological distance measures, from redshift zero to redshift of 0.5. The background cosmology is Hubble parameter 72 km/s/Mpc, Omega_lambda = 0.732, Omega_matter = 0.266, Omega_radiation = 0.266/3454, and Omega_k chosen so that the sum of Omega parameters is one.

light-travel distance - simply the speed of light times the cosmological time interval, i.e. integral of c dt, while the comoving distance is the integral of c dt /a( t ) .
d_L luminosity distance
d_pm proper motion distance
- called the angular size distance by Peebles 1993, but should not be confused with angular diameter distance [1])
- sometimes called the coordinate distance
- sometimes d_pm is called the angular diameter distance
d_a angular diameter distance

The latter three are related by:

d_a = d_pm / (1 + z) = d_L /(1 + z)²

where z is the redshift.

If and only if the curvature is zero, then proper motion distance and comoving distance are identical, i.e. $d pm = χ$ .

For negative curvature,

$d_{\mbox{pm}} = R_C \sinh {\chi \over R_C}$ ,

while for positive curvature,

$d_{\mbox{pm}} = R_C \sin {\chi \over R_C}$ ,

where $R C$ is the (absolute value of the) radius of curvature.

A practical formula for numerically integrating $d p$ to a redshift $z$ for arbitrary values of the matter density parameter $Ω m$ , the cosmological constant $Ω Λ$ , and the quintessence parameter $w$ is

$d_p \equiv \chi(z) = {c \over H_0} \int^{a'=1}_{a'=1/(1+z)} {\mbox{d}a \over a \sqrt{ \Omega_m /a - (\Omega_m + \Omega_\Lambda -1) + \Omega_\Lambda a^{-(1+3w)} } },$

A comparison of cosmological distance measures, from redshift zero to redshift of 10,000, corresponding to the epoch of matter/radiation equality. The background cosmology is Hubble parameter 72 km/s/Mpc, Omega_lambda = 0.732, Omega_matter = 0.266, Omega_radiation = 0.266/3454, and Omega_k chosen so that the sum of Omega parameters is one.

where c is the speed of light and H₀ is the Hubble constant.

By using sin and sinh functions, proper motion distance d_pm can be obtained from d_p.

[edit] See also

[edit] References

P. J. E. Peebles, Principles of Physical Cosmology. Princeton University Press (1993)
Scott Dodelson, Modern Cosmology. Academic Press (2003).

[edit] External links

'The Distance Scale of the Universe' compares different cosmological distance measures.
'Distance measures in cosmology' explains in detail how to calculate the different distance measures as a function of world model and redshift.

Categories: Physical cosmology | Units of length in astronomy

Distance measures (cosmology)

From Wikipedia, the free encyclopedia

Contents

[edit] Types of Distance Measures

[edit] Comparison of Distance Measures

[edit] See also

[edit] References

[edit] External links

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