爱丁顿光度计算器
使用此爱丁顿光度计算器快速获得准确的计算结果。
Eddington Luminosity
14,708,643,955,456,562,000,000,000,000,000.000 W
Eddington Luminosity vs Object Mass
公式
## The Eddington Luminosity The maximum luminosity where radiation pressure on infalling matter balances gravitational attraction. ### Formula **L_Edd = 4π G M c / κ** Using electron-scattering opacity κ ≈ 0.034 m²/kg for ionised hydrogen. For a solar-mass object, L_Edd ≈ 3.3 × 10⁴ L_sun. Exceeding L_Edd causes radiation-driven mass loss (stellar winds, super-Eddington outbursts).
计算示例
A 1-solar-mass object.
- 01L_Edd = 4π G M c / κ
- 02= 4π × 6.674e-11 × 1.989e30 × 2.998e8 / 0.034
- 03Numerator = 4π × 3.979e28 = 4.988e29
- 04L_Edd = 4.988e29 / 0.034 ≈ 1.47e31 W ≈ 38 300 L_sun
常见问题
Can stars exceed the Eddington limit?
Briefly, yes. Super-Eddington luminosities drive powerful mass outflows. Some very massive stars and accreting objects transiently exceed it.
Why does the Eddington limit matter for black holes?
It sets the maximum accretion rate onto a black hole. Faster accretion would blow away the infalling material.
Does opacity affect the limit?
Yes. Higher opacity lowers L_Edd because radiation couples more effectively to matter. The electron-scattering value is a minimum opacity for ionised gas.