The Friedmann Equation
The Master Equation of Cosmic Expansion
What is the Friedmann Equation?
The Friedmann equation is the cornerstone of modern cosmology. Derived from Einstein's field equations of General Relativity by Alexander Friedmann in 1922, it describes how the universe expands or contracts over time. This single equation connects the expansion rate of the universe to its energy content and geometry.
The equation emerges when we apply Einstein's equations to the entire universe, assuming it is homogeneous and isotropic on large scales—a principle known as the Cosmological Principle.
The Equation Itself
The First Friedmann Equation
This is the most commonly referenced form, though there's also a second Friedmann equation that describes acceleration. Let's break down what each symbol represents.
Components of the Equation
Measures the expansion rate of the universe at any given time. H₀ is its current value (Hubble constant), approximately 70 km/s/Mpc.
The fundamental constant of gravity from Newton's law: 6.674 × 10⁻¹¹ m³/kg/s².
The combined density of all cosmic components: ordinary matter, dark matter, radiation, and dark energy.
Determines the geometry of space: +1 (spherical), 0 (flat), or -1 (hyperbolic).
Describes how distances between galaxies change over time. Today, R = 1; in the past, R < 1.
The universal speed limit: 299,792,458 m/s. Appears because we're working in relativity.
Represents dark energy—a constant energy density permeating space, causing accelerated expansion.
Interpreting the Three Terms
1. Expansion Term: H²
The left side of the equation, H², represents the square of the expansion rate. This is what we're solving for—how fast the universe is expanding.
2. Energy Density Term: (8πG/3)ρ
This term represents the contribution from all forms of mass and energy in the universe. It includes:
- Ordinary matter: Atoms, planets, stars, galaxies
- Dark matter: Invisible matter that exerts gravitational pull
- Radiation: Photons and relativistic particles
- Dark energy: Often included in ρ or as the Λ term separately
3. Curvature Term: -kc²/R²
This term describes the geometry of space itself. The value of k determines whether the universe is:
| Curvature (k) | Geometry | Density Relation | Fate of Universe |
|---|---|---|---|
| +1 | Closed (Spherical) | ρ > ρcrit | Eventually recollapses |
| 0 | Flat (Euclidean) | ρ = ρcrit | Expands forever, slowing asymptotically |
| -1 | Open (Hyperbolic) | ρ < ρcrit | Expands forever |
4. Cosmological Constant Term: Λc²/3
Originally introduced by Einstein to allow for a static universe, Λ was later revived to explain the observed acceleration of cosmic expansion. Today, it represents dark energy—a mysterious energy causing expansion to accelerate.
The Critical Density
Critical Density Formula
This is the density required for a flat universe (k=0). Current measurements give ρcrit ≈ 9×10⁻²⁷ kg/m³—equivalent to about 5 hydrogen atoms per cubic meter.
By comparing the actual density ρ to ρcrit, we determine the geometry and fate of the universe:
Flat universe condition: When ρ = ρcrit, the curvature term vanishes, and we have the simple relation H² = (8πG/3)ρ + Λc²/3.
Modern Form with Dark Energy
In contemporary cosmology, dark energy is often treated as a component of ρ rather than a separate Λ term. The equation is frequently written as:
Where the Ω parameters represent density fractions today:
Radiation density (photons, neutrinos): ~0.0001 today
Matter density (ordinary + dark): ~0.31 today
Curvature density: ~0.001 (nearly zero)
Dark energy density: ~0.69 today
Why the Friedmann Equation Matters
The Cosmic Master Equation
The Friedmann equation is the fundamental tool that allows cosmologists to:
- Determine the age of the universe
- Predict the ultimate fate of the cosmos
- Understand the geometry of space on the largest scales
- Relate observable quantities (expansion rate, density) to fundamental physics
- Test cosmological models against observational data
By measuring H₀ and the various Ω parameters through observations of the CMB, supernovae, and galaxy distributions, we can solve the Friedmann equation backwards to understand the history of the universe and forwards to predict its future.
Current consensus: Observations indicate Ωk ≈ 0 (flat universe), ΩM ≈ 0.31, ΩΛ ≈ 0.69. This "ΛCDM" model suggests a flat universe dominated by dark energy, expanding at an accelerating rate.
Summary
The Friedmann equation elegantly encapsulates the relationship between the expansion of space, the energy content of the universe, and its geometry. It transforms the abstract concepts of General Relativity into a practical framework for understanding cosmic evolution—from the Big Bang to the present and into the distant future.
While the equation itself appears simple, its implications are profound, touching on questions about the origin, structure, and ultimate fate of our entire universe.