Some insight into the expansion can be obtained from a Newtonian expansion model which leads to a simplified version of the Friedmann equation. It relates the proper distance (which can change over time, unlike the comoving distance ${\displaystyle d_{C}}$  which is constant and set to today's distance) between a pair of objects, e.g. two galaxy clusters, moving with the Hubble flow in an expanding or contracting FLRW universe at any arbitrary time ${\displaystyle t}$  to their distance at some reference time ${\displaystyle t_{0}}$ . The formula for this is:

${\displaystyle d(t)=a(t)d_{0},\,}$ 

where ${\displaystyle d(t)}$  is the proper distance at epoch ${\displaystyle t}$ , ${\displaystyle d_{0}}$  is the distance at the reference time ${\displaystyle t_{0}}$ , usually also referred to as comoving distance, and ${\displaystyle a(t)}$  is the scale factor.^[3] Thus, by definition, ${\displaystyle d_{0}=d(t_{0})}$  and ${\displaystyle a(t_{0})=1}$ .

The scale factor is dimensionless, with ${\displaystyle t}$  counted from the birth of the universe and ${\displaystyle t_{0}}$  set to the present age of the universe: ${\displaystyle 13.799\pm 0.021\,\mathrm {Gyr} }$ ^[4] giving the current value of ${\displaystyle a}$  as ${\displaystyle a(t_{0})}$  or ${\displaystyle 1}$ .

The evolution of the scale factor is a dynamical question, determined by the equations of general relativity, which are presented in the case of a locally isotropic, locally homogeneous universe by the Friedmann equations.

The Hubble parameter is defined as:

${\displaystyle H(t)\equiv {{\dot {a}}(t) \over a(t)}}$ 

where the dot represents a time derivative. The Hubble parameter varies with time, not with space, with the Hubble constant ${\displaystyle H_{0}}$  being its current value.

From the previous equation ${\displaystyle d(t)=d_{0}a(t)}$  one can see that ${\displaystyle {\dot {d}}(t)=d_{0}{\dot {a}}(t)}$ , and also that ${\displaystyle d_{0}={\frac {d(t)}{a(t)}}}$ , so combining these gives ${\displaystyle {\dot {d}}(t)={\frac {d(t){\dot {a}}(t)}{a(t)}}}$ , and substituting the above definition of the Hubble parameter gives ${\displaystyle {\dot {d}}(t)=H(t)d(t)}$  which is just Hubble's law.

Current evidence suggests that the expansion rate of the universe is accelerating, which means that the second derivative of the scale factor ${\displaystyle {\ddot {a}}(t)}$  is positive, or equivalently that the first derivative ${\displaystyle {\dot {a}}(t)}$  is increasing over time.^[5] This also implies that any given galaxy recedes from us with increasing speed over time, i.e. for that galaxy ${\displaystyle {\dot {d}}(t)}$  is increasing with time. In contrast, the Hubble parameter seems to be decreasing with time, meaning that if we were to look at some fixed distance d and watch a series of different galaxies pass that distance, later galaxies would pass that distance at a smaller velocity than earlier ones.^[6]

According to the Friedmann–Lemaître–Robertson–Walker metric which is used to model the expanding universe, if at present time we receive light from a distant object with a redshift of z, then the scale factor at the time the object originally emitted that light is ${\displaystyle a(t)={\frac {1}{1+z}}}$ .^[7][8]

Radiation-dominated era

After Inflation, and until about 47,000 years after the Big Bang, the dynamics of the early universe were set by radiation (referring generally to the constituents of the universe which moved relativistically, principally photons and neutrinos).^[9]

For a radiation-dominated universe the evolution of the scale factor in the Friedmann–Lemaître–Robertson–Walker metric is obtained solving the Friedmann equations:

${\displaystyle a(t)\propto t^{1/2}.\,}$ ^[10]

Matter-dominated era

Between about 47,000 years and 9.8 billion years after the Big Bang,^[11] the energy density of matter exceeded both the energy density of radiation and the vacuum energy density.^[12]

When the early universe was about 47,000 years old (redshift 3600), mass–energy density surpassed the radiation energy, although the universe remained optically thick to radiation until the universe was about 378,000 years old (redshift 1100). This second moment in time (close to the time of recombination), at which the photons which compose the cosmic microwave background radiation were last scattered, is often mistaken^{[neutrality is disputed]} as marking the end of the radiation era.

For a matter-dominated universe the evolution of the scale factor in the Friedmann–Lemaître–Robertson–Walker metric is easily obtained solving the Friedmann equations:

${\displaystyle a(t)\propto t^{2/3}}$ 

Dark-energy-dominated era

In physical cosmology, the dark-energy-dominated era is proposed as the last of the three phases of the known universe, the other two being the matter-dominated era and the radiation-dominated era. The dark-energy-dominated era began after the matter-dominated era, i.e. when the Universe was about 9.8 billion years old.^[13] In the era of cosmic inflation, the Hubble parameter is also thought to be constant, so the expansion law of the dark-energy-dominated era also holds for the inflationary prequel of the big bang.

The cosmological constant is given the symbol Λ, and, considered as a source term in the Einstein field equation, can be viewed as equivalent to a "mass" of empty space, or dark energy. Since this increases with the volume of the universe, the expansion pressure is effectively constant, independent of the scale of the universe, while the other terms decrease with time. Thus, as the density of other forms of matter – dust and radiation – drops to very low concentrations, the cosmological constant (or "dark energy") term will eventually dominate the energy density of the Universe. Recent measurements of the change in Hubble constant with time, based on observations of distant supernovae, show this acceleration in expansion rate,^[14] indicating the presence of such dark energy.

For a dark-energy-dominated universe, the evolution of the scale factor in the Friedmann–Lemaître–Robertson–Walker metric is easily obtained solving the Friedmann equations:

${\displaystyle a(t)\propto \exp(H_{0}t)}$ 

Here, the coefficient ${\displaystyle H_{0}}$ in the exponential, the Hubble constant, is

${\displaystyle H_{0}={\sqrt {8\pi G\rho _{\mathrm {full} }/3}}={\sqrt {\Lambda /3}}.}$ 

This exponential dependence on time makes the spacetime geometry identical to the de Sitter universe, and only holds for a positive sign of the cosmological constant, which is the case according to the currently accepted value of the cosmological constant, Λ, that is approximately 2 · 10⁻³⁵ s⁻². The current density of the observable universe is of the order of 9.44 · 10⁻²⁷ kg m⁻³ and the age of the universe is of the order of 13.8 billion years, or 4.358 · 10¹⁷ s. The Hubble constant, ${\displaystyle H_{0}}$ , is ≈70.88 km s⁻¹ Mpc⁻¹ (The Hubble time is 13.79 billion years).

• Cosmological principle
• Lambda-CDM model
• Redshift

• Padmanabhan, Thanu (1993). Structure formation in the universe. Cambridge: Cambridge University Press. ISBN 978-0-521-42486-8.
• Spergel, D. N.; et al. (2003). "First-Year Wilkinson Microwave Anisotropy Probe (WMAP) Observations: Determination of Cosmological Parameters". Astrophysical Journal Supplement. 148 (1): 175–194. arXiv:astro-ph/0302209. Bibcode:2003ApJS..148..175S. CiteSeerX 10.1.1.985.6441. doi:10.1086/377226. S2CID 10794058.

• Relation of the scale factor with the cosmological constant and the Hubble constant