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Friedmann equations

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The Friedmann equations, also known as the Friedmann–Lemaître (FL) equations, are a set of equations in physical cosmology that govern cosmic expansion in homogeneous and isotropic models of the universe within the context of general relativity. They were first derived by Alexander Friedmann in 1922 from Einstein's field equations of gravitation for the Friedmann–Lemaître–Robertson–Walker metric and a perfect fluid with a given mass density ρ and pressure p.[1] The equations for negative spatial curvature were given by Friedmann in 1924.[2]

Assumptions

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The Friedmann equations build on three assumptions:[3]: 22.1.3 

  1. the Friedmann–Lemaître–Robertson–Walker metric,
  2. Einstein's equations for general relativity, and
  3. a perfect fluid source.

The metric in turn starts with the simplifying assumption that the universe is spatially homogeneous and isotropic, that is, the cosmological principle; empirically, this is justified on scales larger than the order of 100 Mpc.

The metric can be written as:[4]: 65  where These three possibilities correspond to parameter k of (0) flat space, (+1) a sphere of constant positive curvature or (-1) a hyperbolic space with constant negative curvature. Here the radial position has been decomposed into a time-dependent scale factor, , and a comoving coordinate, . Inserting this metric into Einstein's field equations relate the evolution of this scale factor to the pressure and energy of the matter in the universe. With the stress–energy tensor for a perfect fluid, results in the equations are described below.[4]: 73 

Dimensionless scale factor

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A dimensionless scale factor can be defined: using the present day value

.

The Friedmann equations can be written in terms of this dimensionless scale factor.[citation needed]

Equations

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There are two independent Friedmann equations for modelling a homogeneous, isotropic universe The first is:[3] and second is: The term Friedmann equation sometimes is used only for the first equation.[3] In these equations, R(t) is the cosmological scale factor, is the Newtonian constant of gravitation, Λ is the cosmological constant with dimension length−2, ρ is the energy density and p is the isotropic pressure. k is constant throughout a particular solution, but may vary from one solution to another. The units set the speed of light in vacuum to one.

In previous equations, R, ρ, and p are functions of time. If the cosmological constant, Λ, is ignored, the term in the first Friedmann equation can be interpreted as a Newtonian total energy, so the evolution of the universe pits gravitational potential energy, against kinetic energy, . The winner depends upon the k value in the total energy: if k is +1, gravity eventually causes the universe to contract. These conclusions will be altered if the Λ is not zero.[3]

Using the first equation, the second equation can be re-expressed as:[3] which eliminates Λ. Alternatively the conservation of mass–energy: leads to the same result.[3]

Critical density

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That value of the mass-energy density, that gives when is called the critical density: If the universe has higher density, , then it is called "spatially closed": in this simple approximation the universe would eventually contract. On the other hand, if has higher lower density, , then it is called "spatially open" and expands forever. Therefore the geometry of the universe is directly connected to its density.[4]: 73 

Density parameter

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The density parameter Ω is defined as the ratio of the actual (or observed) density ρ to the critical density ρc of the Friedmann universe:[4]: 74  Both the density and the Hubble parameter depend upon time and thus the density parameter varies with time.[4]: 74 

The critical density is equivalent to approximately five atoms (of monatomic hydrogen) per cubic metre, whereas the average density of ordinary matter in the Universe is believed to be 0.2–0.25 atoms per cubic metre.[5][6]

Estimated relative distribution for components of the energy density of the universe. Dark energy dominates the total energy (74%) while dark matter (22%) constitutes most of the mass. Of the remaining baryonic matter (4%), only one tenth is compact. In February 2015, the European-led research team behind the Planck cosmology probe released new data refining these values to 4.9% ordinary matter, 25.9% dark matter and 69.1% dark energy.

A much greater density comes from the unidentified dark matter, although both ordinary and dark matter contribute in favour of contraction of the universe. However, the largest part comes from so-called dark energy, which accounts for the cosmological constant term. Although the total density is equal to the critical density (exactly, up to measurement error), dark energy does not lead to contraction of the universe but rather may accelerate its expansion.

An expression for the critical density is found by assuming Λ to be zero (as it is for all basic Friedmann universes) and setting the normalised spatial curvature, k, equal to zero. When the substitutions are applied to the first of the Friedmann equations given the new value we find:[7] where:

*

*

*

Given the value of dark energy to be This term originally was used as a means to determine the spatial geometry of the universe, where ρc is the critical density for which the spatial geometry is flat (or Euclidean). Assuming a zero vacuum energy density, if Ω is larger than unity, the space sections of the universe are closed; the universe will eventually stop expanding, then collapse. If Ω is less than unity, they are open; and the universe expands forever. However, one can also subsume the spatial curvature and vacuum energy terms into a more general expression for Ω in which case this density parameter equals exactly unity. Then it is a matter of measuring the different components, usually designated by subscripts. According to the ΛCDM model, there are important components of Ω due to baryons, cold dark matter and dark energy. The spatial geometry of the universe has been measured by the WMAP spacecraft to be nearly flat. This means that the universe can be well approximated by a model where the spatial curvature parameter k is zero; however, this does not necessarily imply that the universe is infinite: it might merely be that the universe is much larger than the part we see.

The first Friedmann equation is often seen in terms of the present values of the density parameters, that is[8] Here Ω0,R is the radiation density today (when a = 1), Ω0,M is the matter (dark plus baryonic) density today, Ω0,k = 1 − Ω0 is the "spatial curvature density" today, and Ω0,Λ is the cosmological constant or vacuum density today.

Other forms

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These equations are sometimes simplified by replacing to give:

The simplified form of the second equation is invariant under this transformation.

The Hubble parameter can change over time if other parts of the equation are time dependent (in particular the mass density, the vacuum energy, or the spatial curvature). Evaluating the Hubble parameter at the present time yields Hubble's constant which is the proportionality constant of Hubble's law. Applied to a fluid with a given equation of state, the Friedmann equations yield the time evolution and geometry of the universe as a function of the fluid density.

We see that in the Friedmann equations, a(t) does not depend on which coordinate system we chose for spatial slices. There are two commonly used choices for a and k which describe the same physics:

  • k = +1, 0 or −1 depending on whether the shape of the universe is a closed 3-sphere, flat (Euclidean space) or an open 3-hyperboloid, respectively.[9] If k = +1, then a is the radius of curvature of the universe. If k = 0, then a may be fixed to any arbitrary positive number at one particular time. If k = −1, then (loosely speaking) one can say that i · a is the radius of curvature of the universe.
  • a is the scale factor which is taken to be 1 at the present time. k is the current spatial curvature (when a = 1). If the shape of the universe is hyperspherical and Rt is the radius of curvature (R0 at the present), then a = Rt/R0. If k is positive, then the universe is hyperspherical. If k = 0, then the universe is Euclidean (flat). If k is negative, then the universe has hyperbolic geometry.

Useful solutions

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The Friedmann equations can be solved exactly in presence of a perfect fluid with equation of state where p is the pressure, ρ is the mass density of the fluid in the comoving frame and w is some constant.

In spatially flat case (k = 0), the solution for the scale factor is where a0 is some integration constant to be fixed by the choice of initial conditions. This family of solutions labelled by w is extremely important for cosmology. For example, w = 0 describes a matter-dominated universe, where the pressure is negligible with respect to the mass density. From the generic solution one easily sees that in a matter-dominated universe the scale factor goes as matter-dominated Another important example is the case of a radiation-dominated universe, namely when w = 1/3. This leads to radiation-dominated

Note that this solution is not valid for domination of the cosmological constant, which corresponds to an w = −1. In this case the energy density is constant and the scale factor grows exponentially.

Solutions for other values of k can be found at Tersic, Balsa. "Lecture Notes on Astrophysics". Retrieved 24 February 2022.

Mixtures

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If the matter is a mixture of two or more non-interacting fluids each with such an equation of state, then holds separately for each such fluid f. In each case, from which we get

For example, one can form a linear combination of such terms where A is the density of "dust" (ordinary matter, w = 0) when a = 1; B is the density of radiation (w = 1/3) when a = 1; and C is the density of "dark energy" (w = −1). One then substitutes this into and solves for a as a function of time.

History

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Alexander Friedmann

Friedmann published two cosmology papers in the 1922-1923 time frame. He adopted the same homogeneity and isotropy assumptions used by Albert Einstein and by Willem de Sitter in their papers, both published in 1917. Both of the earlier works also assumed the universe was static, eternally unchanging. Einstein postulated an additional term to his equations of general relativity to ensure this stability. In his paper, de Sitter showed that spacetime had curvature even in the absence of matter: the new equations of general relativity implied that a vacuum had properties that altered spacetime.[10]: 152 

The idea of static universe was a fundamental assumption of philosophy and science. However, Friedmann abandoned the idea in his first paper "On the curvature of space". Starting with Einstein's 10 equations of relativity, Friedmann applies the symmetry of an isotropic universe and a simple model for mass-energy density to derive a relationship between that density and the curvature of spacetime. He demonstrates that in addition to one solution is static, many time dependent solutions also exist.[10]: 157 

Friedmann's second paper, "On the possibility of a world with constant negative curvature," published in 1924 explored more complex geometrical ideas. This paper establish the idea that that the finiteness of spacetime was not a property that could be established based on the equations of general relativity alone: both finite and infinite geometries could be used to give solutions. Friedmann used two concepts of a three dimensional sphere as analogy: a trip at constant latitude could return to the starting point or the sphere might have an infinite number of sheets and the trip never repeats.[10]: 167 

Friedmann's paper were largely ignored except – initially – by Einstein who actively dismissed them. However once Edwin Hubble publish convincing astronomical evidence that the universe was expanding, Einstein became convinced. Unfortunately for Friedmann, Georges Lemaître discovered some aspects of the same solutions and wrote persuasively about the concept of a universe born from a "primodidal atom". Thus historians give these two scientists equal billing for the discovery.[11]

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Several students at Tsinghua University (CCP leader Xi Jinping's alma mater) participating in the 2022 COVID-19 protests in China carried placards with Friedmann equations scrawled on them, interpreted by some as a play on the words "Free man". Others have interpreted the use of the equations as a call to “open up” China and stop its Zero Covid policy, as the Friedmann equations relate to the expansion, or “opening” of the universe.[12]

See also

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Sources

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  1. ^ Friedman, A (1922). "Über die Krümmung des Raumes". Z. Phys. (in German). 10 (1): 377–386. Bibcode:1922ZPhy...10..377F. doi:10.1007/BF01332580. S2CID 125190902. (English translation: Friedman, A (1999). "On the Curvature of Space". General Relativity and Gravitation. 31 (12): 1991–2000. Bibcode:1999GReGr..31.1991F. doi:10.1023/A:1026751225741. S2CID 122950995.). The original Russian manuscript of this paper is preserved in the Ehrenfest archive.
  2. ^ Friedmann, A (1924). "Über die Möglichkeit einer Welt mit konstanter negativer Krümmung des Raumes". Z. Phys. (in German). 21 (1): 326–332. Bibcode:1924ZPhy...21..326F. doi:10.1007/BF01328280. S2CID 120551579. (English translation: Friedmann, A (1999). "On the Possibility of a World with Constant Negative Curvature of Space". General Relativity and Gravitation. 31 (12): 2001–2008. Bibcode:1999GReGr..31.2001F. doi:10.1023/A:1026755309811. S2CID 123512351.)
  3. ^ a b c d e f Navas, S.; et al. (Particle Data Group) (2024). "Review of Particle Physics". Physical Review D. 110 (3): 1–708. doi:10.1103/PhysRevD.110.030001. 22.1.3 The Friedmann equations of motion
  4. ^ a b c d e Peacock, J. A. (1998-12-28). Cosmological Physics (1 ed.). Cambridge University Press. doi:10.1017/cbo9780511804533. ISBN 978-0-521-41072-4.
  5. ^ Rees, Martin (2001). Just six numbers: the deep forces that shape the universe. Astronomy/science (Repr. ed.). New York, NY: Basic Books. ISBN 978-0-465-03673-8.
  6. ^ "Universe 101". NASA. Retrieved September 9, 2015. The actual density of atoms is equivalent to roughly 1 proton per 4 cubic meters.
  7. ^ Scolnic, Daniel; Riess, Adam G.; Murakami, Yukei S.; Peterson, Erik R.; Brout, Dillon; Acevedo, Maria; Carreres, Bastien; Jones, David O.; Said, Khaled; Howlett, Cullan; Anand, Gagandeep S. (2025-01-15). "The Hubble Tension in Our Own Backyard: DESI and the Nearness of the Coma Cluster". The Astrophysical Journal Letters. 979 (1): L9. arXiv:2409.14546. Bibcode:2025ApJ...979L...9S. doi:10.3847/2041-8213/ada0bd. ISSN 2041-8205.
  8. ^ Nemiroff, Robert J.; Patla, Bijunath (2008). "Adventures in Friedmann cosmology: A detailed expansion of the cosmological Friedmann equations". American Journal of Physics. 76 (3): 265–276. arXiv:astro-ph/0703739. Bibcode:2008AmJPh..76..265N. doi:10.1119/1.2830536. S2CID 51782808.
  9. ^ D'Inverno, Ray (2008). Introducing Einstein's relativity (Repr ed.). Oxford: Clarendon Press. ISBN 978-0-19-859686-8.
  10. ^ a b c Tropp, Eduard A.; Frenkel, Viktor Ya.; Chernin, Artur D. (1993-06-03). Alexander A Friedmann: The Man who Made the Universe Expand. Translated by Dron, Alexander; Burov, Michael (1 ed.). Cambridge University Press. doi:10.1017/cbo9780511608131. ISBN 978-0-521-38470-4.
  11. ^ Belenkiy, Ari (2012-10-01). "Alexander Friedmann and the origins of modern cosmology". Physics Today. 65 (10): 38–43. doi:10.1063/PT.3.1750. ISSN 0031-9228.
  12. ^ Murphy, Matt (November 28, 2022). "China's protests: Blank paper becomes the symbol of rare demonstrations". BBC News.

Further reading

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