Hubble's law

Hubble's law is a statement in physical cosmology which states that the redshift in light coming from distant galaxies is proportional to their distance. The law was first formulated by Edwin Hubble and Milton Humason in 1929^[1] after nearly a decade of observations. It is considered the first observational basis for the expanding space paradigm and today serves as one of the most often cited pieces of evidence in support of the Big Bang. The most recent calculation of the proportionality constant, using the satellite WMAP began in 2003 and a combination of other astronomical data, yielding a value of 70.1 ± 1.3(km/s)/megaparsec. In August, 2006, a less accurate figure was obtained independently using data from NASA's orbital Chandra X-ray Observatory: 77 (km/s)/Mpc or about 2.5×10⁻¹⁸ s⁻¹ with an uncertainty of ± 15%.^[2]

[edit] Discovery

[edit] FLRW equations

[edit] Shape of the universe

Before the advent of modern cosmology, there was considerable talk about the size and shape of the universe. In 1920, the famous Shapley-Curtis debate took place between Harlow Shapley and Heber D. Curtis over this issue. Shapley argued for a small universe the size of the Milky Way galaxy and Curtis argued that the universe was much larger. The issue would be resolved in the coming decade with Hubble's improved observations.

[edit] Cepheid variable stars outside of the Milky Way

Edwin Powell Hubble did most of his professional astronomical observing work at Mount Wilson Observatory, the world's most powerful telescope at the time. His observations of Cepheid variable stars in spiral nebulae enabled him to calculate the distances to these objects. Surprisingly, these objects were discovered to be at distances which placed them well outside the Milky Way. The nebulae were first described as "island universes" and it was only later that the moniker "galaxy" would be applied to them.

[edit] Combining redshifts with distance measurements

Combining his measurements of galaxy distances with Vesto Slipher's measurements of the redshifts associated with the galaxies, Hubble discovered a rough proportionality of the objects' distances. Though there was considerable scatter (now known to be caused by peculiar velocities), Hubble was able to plot a trend line from the 46 galaxies he studied and obtain a value for the Hubble constant of 500 km/s/Mpc (much higher than the currently accepted value due to errors in his distance calibrations). (See cosmic distance ladder for details.)

In 1958, the first good estimate of H₀, 75 km/s/Mpc, was published by Allan Sandage^[4], but it would be decades before a consensus was achieved.

[edit] The cosmological constant abandoned

After Hubble's discovery was published, Albert Einstein abandoned his work on the cosmological constant (which he had designed to allow for a static solution to his equations). He would later term this work his "greatest blunder" since the belief of a static universe prevented him from predicting the expanding universe. Einstein would make a famous trip to Mount Wilson in 1931 to thank Hubble for providing the observational basis for modern cosmology.

[edit] Interpretation

The discovery of the linear relationship between redshift, interpreted as recessional velocity, and distance yields a straightforward mathematical expression for Hubble's Law as follows:

[edit] Superluminal speeds

As the formula implies, in very distant objects, v can be greater than c. This is not a violation of special relativity, because the rules of special relativity only apply precisely within a small region: a special-relativistic description of two widely-separated galaxies would in general be incorrect. (Thus special relativity strictly says, not that no speed can be faster than light, but that nothing can move past another object at a speed faster than light).^{[citation needed]}

[edit] Observability of parameters

Strictly speaking, neither v nor D in the formula are directly observable, because they are properties now of a galaxy, whereas our observations refer to the galaxy in the past, at the time that the light we currently see left it.

For relatively nearby galaxies (redshift z much less than unity), v and D will not have changed much, and v can be estimated using the formula Failed to parse (Missing texvc executable; please see math/README to configure.): v = zc

For distant galaxies, v (or D) cannot be calculated from z without specifying a detailed model for how H changes with time. The redshift is not even directly related to the recession velocity at the time the light set out, but it does have a simple interpretation: (1+z) is the factor by which the universe has expanded while the photon was travelling towards the observer.

[edit] Expansion velocity vs relative velocity

In using Hubble's law to determine distances, only the velocity due to the expansion of the universe can be used. Since gravitationally interacting galaxies move relative to each other independent of the expansion of the universe, these relative velocities, called peculiar velocities, need to be accounted for in the application of Hubble's law.

The Finger of God effect is one result of this phenomenon discovered in 1938 by Benjamin Kenneally. In systems that are gravitationally bound, such as galaxies or our planetary system, the expansion of space is (more than) annihilated by the attractive force of gravity.

[edit] Idealized Hubble's Law

The mathematical derivation of an idealized Hubble's Law for a uniformly expanding universe is a fairly elementary theorem of geometry in 3-dimensional Cartesian/Newtonian coordinate space, which, considered as a metric space, is entirely homogeneous and isotropic (properties do not vary with location or direction). Simply stated the theorem is this:

In fact this applies to non-Cartesian spaces as long as they are locally homogeneous and isotropic; specifically to the negatively- and positively-curved spaces frequently considered as cosmological models (see shape of the universe).

[edit] The Ultimate fate and age of the universe

The ultimate fate of the universe and the age of the universe can both be determined by measuring the Hubble constant today and extrapolating with the observed value of the deceleration parameter, uniquely characterized by values of density parameters (Ω). A so-called "closed universe" (Ω>1) comes to an end in a Big Crunch and is considerably younger than its Hubble age. An "open universe" (Ω≤1) expands forever and has an age that is closer its Hubble age. For the accelerating universe that we inhabit, the age of the universe is coincidentally very close to the Hubble age.

The value of the Hubble parameter changes over time either increasing or decreasing depending on the sign of the so-called deceleration parameter Failed to parse (Missing texvc executable; please see math/README to configure.): q

please see math/README to configure.): q = -\left(1+\frac{\dot H}{H^2}\right).

In a universe with a deceleration parameter equal to zero, it follows that H = 1/t, where t is the time since the Big Bang. A non-zero, time-dependent value of Failed to parse (Missing texvc executable; please see math/README to configure.): q

It was long thought that q was positive, indicating that the expansion is slowing down due to gravitational attraction. This would imply an age of the universe less than 1/H (which is about 14 billion years). For instance, a value for q of 1/2 (once favoured by most theorists) would give the age of the universe as 2/(3H). The discovery in 1998 that q is apparently negative means that the universe could actually be older than 1/H. In fact, estimates of the age of the universe are, by coincidence, very close to 1/H.

[edit] Olbers' paradox

The expansion of space summarized by the Big Bang interpretation of Hubble's Law is relevant to the old conundrum known as Olbers' paradox: if the universe were infinite, static, and filled with a uniform distribution of stars (notice that this also requires an infinite number of stars), then every line of sight in the sky would end on a star, and the sky would be as bright as the surface of a star. However, the night sky is largely dark. Since the 1600s, astronomers and other thinkers have proposed many possible ways to resolve this paradox, but the currently accepted resolution depends in part upon the Big Bang theory and in part upon the Hubble expansion. In a universe that exists for a finite amount of time, only the light of finitely many stars has had a chance to reach us yet, and the paradox is resolved. Additionally, in an expanding universe distant objects recede from us which cause the light emanating from them to be redshifted and diminished in brightness. Both effects contribute (the redshift being the more important of the two; remember the original paradox was couched in terms of a static universe). The darkness of the night sky, then, provides a kind of confirmation for the Hubble expansion of the universe. ^[5]

[edit] Determining the Hubble constant

The value of the Hubble constant is estimated by measuring the redshift of distant galaxies and then determining the distances to the same galaxies (by some other method than Hubble's law). Uncertainties in the physical assumptions used to determine these distances have caused varying estimates of the Hubble constant. For most of the second half of the 20th century the value of Failed to parse (Missing texvc executable; please see math/README to configure.): H_0

[edit] Disputes over Hubble's constant

The value of the Hubble constant was the topic of a long and rather bitter controversy between Gérard de Vaucouleurs who claimed the value was around 100 and Allan Sandage who claimed the value was near 50.

This difference was partially resolved with the introduction of the ΛCDM model of the universe in the late 1990s.

[edit] The ΛCDM model

With the ΛCDM model observations of high-redshift clusters at X-ray and microwave wavelengths using the Sunyaev-Zel'dovich effect, measurements of anisotropies in the cosmic microwave background radiation, and optical surveys all gave a value of around 70 for the constant.

[edit] Using Hubble space telescope data

In particular the Hubble Key Project (led by Dr. Wendy L. Freedman, Carnegie Observatories) gave the most accurate optical determination in May 2001 with its final estimate^[6] of 72±8 (km/s)/Mpc, consistent with a measurement of Failed to parse (Missing texvc executable; please see math/README to configure.): H_0

[edit] Using WMAP data

The most precise cosmic microwave background radiation determinations were 71±4 (km/s)/Mpc, by WMAP in 2003, and 70.4^+1.5_−1.6 (km/s)/Mpc, for measurements up to 2006.^[7] The five year release from WMAP in 2008 finds 71.9+2.6−2.7 (km/s)/Mpc.[1]

These values arise from fitting a combination of WMAP and other cosmological data to the simplest version of the ΛCDM model. If the data is fitted with more general versions, Failed to parse (Missing texvc executable; please see math/README to configure.): H_0

[edit] Using Chandra X-ray Observatory data

In August 2006, using NASA's Chandra X-ray Observatory, a team from NASA's Marshall Space Flight Center (MSFC) found the Hubble constant to be 77 (km/s)/Mpc, with an uncertainty of about 15%. ^[9] The consistency of the measurements from all these methods lends support to both the measured value of Failed to parse (Missing texvc executable; please see math/README to configure.): H_0

[edit] Acceleration of the expansion

A value for Failed to parse (Missing texvc executable; please see math/README to configure.): q

[edit] Derivation of the Hubble parameter

please see math/README to configure.): H^2 \equiv \left(\frac{\dot{a}}{a}\right)^2 = \frac{8 \pi G}{3}\rho - \frac{kc^2}{a^2}+ \frac{\Lambda c^2}{3},

where Failed to parse (Missing texvc executable; please see math/README to configure.): H

[edit] Matter-dominated universe (with a cosmological constant)

If the universe is matter-dominated, then the mass density of the universe Failed to parse (Missing texvc executable; please see math/README to configure.): \rho

please see math/README to configure.): \rho = \rho_m(a) = \frac{\rho_{m_{0}}}{a^3},

where Failed to parse (Missing texvc executable; please see math/README to configure.): \rho_{m_{0}}

please see math/README to configure.): \Omega_m \equiv \frac{\rho_{m_{0}}}{\rho_c} = \frac{8 \pi G}{3 H_0^2}\rho_{m_{0}};

so Failed to parse (Missing texvc executable; please see math/README to configure.): \rho=\rho_c \Omega_m /a^3.

please see math/README to configure.): \Omega_k \equiv \frac{-kc^2}{(a_0H_0)^2}

please see math/README to configure.): \Omega_{\Lambda} \equiv \frac{\Lambda c^2}{3H_0^2},

where the subscript nought refers to the values today, and Failed to parse (Missing texvc executable; please see math/README to configure.): a_0=1 . Substituting all of this in into the Friedman equation at the start of this section and replacing Failed to parse (Missing texvc executable; please see math/README to configure.): a

please see math/README to configure.): H^2(z)= H_0^2 \left( \Omega_M (1+z)^{3} + \Omega_k (1+z)^{2} + \Omega_{\Lambda} \right).

[edit] Matter- and dark energy-dominated universe

where Failed to parse (Missing texvc executable; please see math/README to configure.): \rho_{de}

please see math/README to configure.): P=w\rho c^2 , and if we substitute this into the fluid equation, which describes how the mass density of the universe evolves with time,

please see math/README to configure.): \dot{\rho}+3\frac{\dot{a}}{a}\left(\rho+\frac{P}{c^2}\right)=0;

please see math/README to configure.): \frac{d\rho}{\rho}=-3\frac{da}{a}\left(1+w\right).

Therefore for dark energy with a constant equation of state w, Failed to parse (Missing texvc executable; please see math/README to configure.): \rho_{de}(a)= \rho_{de0}a^{-3\left(1+w\right)} . If we substitute this into the Friedman equation in a similar way as before, but this time set Failed to parse (Missing texvc executable; please see math/README to configure.): k=0

please see math/README to configure.): H^2(z)= H_0^2 \left( \Omega_M (1+z)^{3} + \Omega_{de}(1+z)^{-3\left(1+w \right)} \right).

please see math/README to configure.): \rho_{de}(a)= \rho_{de0}e^{-3\int\frac{da}{a}\left(1+w(a)\right)},

and to solve this we must parametrize Failed to parse (Missing texvc executable; please see math/README to configure.): w(a) , for example if Failed to parse (Missing texvc executable; please see math/README to configure.): w(a)=w_0+w_a(1-a) , giving

please see math/README to configure.): H^2(z)= H_0^2 \left( \Omega_M a^{-3} + \Omega_{de}a^{-3\left(1+w_0 +w_a \right)}e^{-3w_a(1-a)} \right).

[edit] Units derived from the Hubble constant

[edit] Hubble time

The Hubble constant Failed to parse (Missing texvc executable; please see math/README to configure.): H_0

please see math/README to configure.): 1/H_0 . The value of Hubble time in the standard cosmological model is 4.35×10¹⁷ s or 13.8 billion years (Liddle 2003, p. 57).

[edit] Hubble length

The Hubble length is a unit of distance in cosmology, defined as Failed to parse (Missing texvc executable; please see math/README to configure.): c/H_0 —the speed of light multiplied by the Hubble time. It is equivalent to 4228 million parsecs or 13.8 billion light years. (The numerical value of the Hubble length in light years is, by definition, equal to that of the Hubble time in years.)

[edit] Hubble volume

The Hubble volume is sometimes defined as a volume of the universe with a comoving size of Failed to parse (Missing texvc executable; please see math/README to configure.): c/H_0 . The exact definition varies: it is sometimes defined as the volume of a sphere with radius Failed to parse (Missing texvc executable; please see math/README to configure.): c/H_0 , or alternatively, a cube of side Failed to parse (Missing texvc executable; please see math/README to configure.): c/H_0 . Some cosmologists even use the term Hubble volume to refer to the volume of the observable universe, although this has a radius approximately 3 times larger.

[edit] See also

[edit] Notes

^ Hubble, Edwin, "A Relation between Distance and Radial Velocity among Extra-Galactic Nebulae" (1929) Proceedings of the National Academy of Sciences of the United States of America, Volume 15, Issue 3, pp. 168-173 (Full article, PDF)
^ Chandra Confirms the Hubble Constant (2006-08-08). Retrieved on 2007-03-07.
^ Friedman, A: Über die Krümmung des Raumes, Z. Phys. 10 (1922), 377-386. (English translation in: Gen. Rel. Grav. 31 (1999), 1991-2000.)
^ Huchra, John. The Hubble Constant. Retrieved on 2007-10-04.
^ S. I. Chase, Olbers' Paradox, entry in the Physics FAQ; see also I. Asimov, "The Black of Night", in Asimov on Astronomy (Doubleday, 1974), ISBN 0-385-04111-X.
^ W. L. Freedman, B. F. Madore, B. K. Gibson, L. Ferrarese, D. D. Kelson, S. Sakai, J. R. Mould, R. C. Kennicutt, Jr., H. C. Ford, J. A. Graham, J. P. Huchra, S. M. G. Hughes, G. D. Illingworth, L. M. Macri, P. B. Stetson. "Final Results from the Hubble Space Telescope Key Project to Measure the Hubble Constant". The Astrophysical Journal 553 (1): 47-72. . Preprint available here.
^ D. N. Spergel et al. (2007), “Three-year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Implications for Cosmology”, Astrophysical Journal Supplement Series 170: 377–408 ; available online at LAMBDA
^ Results for Failed to parse (Missing texvc executable; please see math/README to configure.): H_0 and other cosmological parameters obtained by fitting a variety of models to several combinations of WMAP and other data are available at the NASA's LAMBDA website.
^ Chandra independently determines Hubble constant in Spaceflight Now

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