Eddington Luminosity Calculator
Find the maximum luminosity a compact object can sustain before radiation pressure overcomes gravity, and the critical accretion rate at that limit.
💡 What is the Eddington Luminosity?
The Eddington luminosity (also called the Eddington limit) is the maximum luminosity a gravitationally bound object can emit through steady accretion before radiation pressure overcomes gravity. At this critical value, the outward force of photon pressure on ionised hydrogen exactly balances the inward gravitational pull. The formula was derived by Sir Arthur Eddington in 1916 using the equilibrium condition for stellar structure.
The Eddington limit applies most usefully to compact accreting objects: neutron stars in X-ray binaries, stellar-mass black holes, and supermassive black holes at the centres of galaxies. When an X-ray binary shines near 10 to the 38 watts, it is close to its Eddington limit. When quasars outshine entire galaxies, they are accreting close to the Eddington rate for hundred-million solar mass black holes.
A common misconception is that the Eddington limit is absolute. In practice, sources can briefly exceed it through geometric beaming (where emission is not isotropic), super-Eddington winds, or radiation-dominated columns above neutron star surfaces. Ultraluminous X-ray sources (ULXs) are thought to be stellar-mass objects in super-Eddington accretion states.
The accretion rate at the Eddington limit, called the Eddington accretion rate, depends on the assumed radiative efficiency. This calculator uses the standard thin-disk value of 10 percent. Higher efficiency (relevant for rapidly spinning black holes) reduces the required accretion rate; lower efficiency (slim disks, advection-dominated flows) increases it. The Eddington accretion rate is a key parameter for modelling black hole growth over cosmic time.
📐 Formula
📖 How to Use This Calculator
Steps
💡 Example Calculations
Example 1 — Stellar-Mass Black Hole (10 M☉)
Cygnus X-1 type black hole: mass = 10 solar masses
Example 2 — Sgr A* (Milky Way Central Black Hole, 4 × 106 M☉)
Sagittarius A*: mass = 4,000,000 solar masses
Example 3 — Finding Black Hole Mass from Quasar Luminosity
A quasar shines at 1013 solar luminosities (near Eddington limit)
❓ Frequently Asked Questions
🔗 Related Calculators
What is the Eddington luminosity for a 10 solar mass black hole?
For a 10 solar mass black hole, the Eddington luminosity is approximately 329,000 solar luminosities, or 1.26e32 watts. This is the maximum sustained luminosity before radiation pressure disrupts the infalling material.
Why do neutron stars and black holes have Eddington limits?
The Eddington limit arises because photons carry momentum. When outward radiation pressure on infalling ionised hydrogen equals the inward gravitational force, further accretion is halted. The limit depends only on the mass and fundamental constants.
Can objects exceed the Eddington luminosity?
Yes, temporarily. Gamma-ray bursts, ultraluminous X-ray sources, and some novae exceed the Eddington limit through geometric beaming, super-Eddington winds, or short-lived outbursts where radiation pressure has not yet had time to act.
What is the Eddington accretion rate?
The Eddington accretion rate is the mass inflow rate that produces the Eddington luminosity, given a radiative efficiency. For 10 percent efficiency, it equals L_Edd divided by 0.1 times c squared.
How does the Eddington limit apply to quasars?
Quasars are supermassive black holes accreting near their Eddington limits. A quasar with luminosity 10 to the 13 solar luminosities implies a black hole mass of roughly 300 million solar masses.
Does the Eddington limit depend on the type of accreting material?
The standard formula assumes fully ionised hydrogen, where opacity is dominated by Thomson electron scattering. For helium-rich or metal-rich plasmas the limit differs slightly, but the hydrogen approximation is standard for most applications.
What is the Eddington luminosity for Sgr A*?
Sgr A* has a mass of about 4 million solar masses, giving an Eddington luminosity of roughly 131 billion solar luminosities. Today it accretes far below this limit and is very dim compared to active galactic nuclei.
Is the Eddington limit the same for all types of compact objects?
The formula is the same for black holes, neutron stars, and white dwarfs. However, the physical consequence differs: for white dwarfs, exceeding the limit can trigger a Type Ia supernova rather than disrupting an accretion disk.