Chandrasekhar Limit Calculator
Find the maximum mass a white dwarf can support before electron degeneracy pressure fails and the star collapses.
💥 What is the Chandrasekhar Limit?
The Chandrasekhar limit is the maximum mass that a white dwarf star can have while still being supported against gravitational collapse by electron degeneracy pressure. For the most common white dwarf compositions, this limit is approximately 1.44 solar masses. A white dwarf that exceeds this mass cannot exist in stable equilibrium and will either collapse into a neutron star or detonate as a Type Ia supernova.
White dwarfs are the remnants of stars like our Sun that have exhausted their nuclear fuel. Without active fusion, they are supported entirely by the quantum mechanical pressure that arises because electrons, as fermions, cannot occupy the same quantum state. This pressure is called electron degeneracy pressure, and unlike thermal pressure it does not depend on temperature. However, when the mass grows too large, relativistic effects reduce the effectiveness of this pressure and a critical threshold is reached.
The limit was derived by the Indian-American astrophysicist Subrahmanyan Chandrasekhar in 1930, when he was just 19 years old and traveling by ship from India to England. He combined special relativity with the Fermi-Dirac statistics of electrons to show that a degenerate star above about 1.4 solar masses could not be stable. The result was controversial at first, but was later confirmed and earned Chandrasekhar the 1983 Nobel Prize in Physics.
The Chandrasekhar limit is fundamental to two major areas of modern astrophysics. In stellar evolution, it marks the boundary between white dwarf stability and catastrophic collapse. In cosmology, it underpins the use of Type Ia supernovae as standard candles for measuring cosmic distances, which led to the 1998 discovery of the accelerating expansion of the universe. This calculator lets you compute the limit for any composition and check whether a given white dwarf mass is safely below it.
📐 Formula
The constant 5.83 comes from integrating the Lane-Emden equation for a relativistic polytrope with index n = 3, combined with the ratio of fundamental constants (ℏ c / G)3/2. The formula shows that the limit scales as 1/μe2: compositions with a higher mass-to-electron ratio produce a lower limit.
📖 How to Use This Calculator
Steps
💡 Example Calculations
Example 1 — Standard Carbon-Oxygen White Dwarf
Carbon-oxygen white dwarf with μe = 2.0
Example 2 — Iron-Peak Composition
Iron-peak white dwarf core with μe = 2.15
Example 3 — Checking Stability of a Near-Limit White Dwarf
White dwarf mass 1.37 M☉ with C/O composition (μe = 2.0)
❓ Frequently Asked Questions
🔗 Related Calculators
What is the Chandrasekhar limit in solar masses?
The Chandrasekhar limit is approximately 1.4 solar masses for a carbon-oxygen white dwarf with a mean molecular weight per electron of 2.0. The precise value from the formula M_Ch = 5.83 / mue^2 is 1.4575 solar masses, close to the commonly quoted 1.44.
What happens when a white dwarf exceeds the Chandrasekhar limit?
When a white dwarf exceeds the Chandrasekhar limit, electron degeneracy pressure can no longer counteract gravity. The star either collapses into a neutron star or, more commonly in binary systems, triggers a Type Ia supernova. Type Ia supernovae are used as standard candles to measure cosmic distances.
Why does the Chandrasekhar limit depend on composition?
The limit depends on the mean molecular weight per electron (mue), which is the average number of atomic mass units per electron. For helium, carbon, and oxygen, mue is 2 because these nuclei have equal numbers of protons and neutrons. For iron-peak elements, the neutron-to-proton ratio is slightly higher, raising mue and lowering the limit.
Who derived the Chandrasekhar limit and when?
Subrahmanyan Chandrasekhar derived the limit in 1930 at age 19 during a ship voyage from India to England. He published the full relativistic treatment in 1931 and 1935. The discovery earned him a share of the 1983 Nobel Prize in Physics.
Is the Chandrasekhar limit exactly 1.44 solar masses?
The 1.44 solar mass figure is a rounded approximation. The exact value depends on the equation of state and the white dwarf composition. For mue = 2.0, the formula 5.83 / mue^2 gives 1.4575 solar masses. Corrections for rotation and magnetic fields can shift the limit slightly.
Can a white dwarf be more massive than the Chandrasekhar limit?
In theory, rapid rotation or strong magnetic fields can allow super-Chandrasekhar white dwarfs with masses up to about 2.0 to 2.8 solar masses. These exotic objects are inferred from some over-luminous Type Ia supernovae, but they are not in stable equilibrium the way normal white dwarfs are.
What is the mean molecular weight per electron?
The mean molecular weight per electron (mue) is the average mass per electron in units of the proton mass. For fully ionized matter it equals A / Z, where A is the mass number and Z is the atomic number. For helium (A=4, Z=2), carbon (A=12, Z=6), and oxygen (A=16, Z=8), mue = 2. For iron (A=56, Z=26), mue = 56/26 = 2.15.
What is a Type Ia supernova and how does it relate to the Chandrasekhar limit?
A Type Ia supernova occurs when a white dwarf in a binary system accretes enough mass to approach or exceed the Chandrasekhar limit. The runaway carbon fusion ignites and destroys the entire star. Because the trigger mass is nearly constant, Type Ia supernovae have nearly uniform peak luminosity, making them reliable cosmological distance indicators.
Do neutron stars have an equivalent to the Chandrasekhar limit?
Yes. The Tolman-Oppenheimer-Volkoff (TOV) limit plays the same role for neutron stars that the Chandrasekhar limit plays for white dwarfs. Above the TOV limit, neutron degeneracy pressure fails and the star collapses into a black hole. The TOV limit is estimated between 2 and 3 solar masses depending on the nuclear equation of state.
What is the formula for the Chandrasekhar limit?
The formula is M_Ch = 5.83 / mue^2 solar masses, derived from relativistic quantum mechanics. The constant 5.83 comes from the ratio (hbar c / G)^(3/2) times a dimensionless factor of order unity from integrating the Lane-Emden polytrope solution for index n = 3.