Stellar evolution

The Circle of Life

Deep in the Core

Final Destinations

Stellar Anatomy

Under Pressure

100

This is the primary factor that determines the specific life path a star will take and how long it will live.

Initial Mass

100

This is the primary energy source (fusion sequence) for stars with masses less than 1.5 times the mass of the Sun.

Proton-proton chain

100

This is the extremely dense, hot core remnant left behind after a low-mass star sheds its outer layers.

White Dwarf

100

This is the star's visible "surface" from which light finally escapes into space.

Photosphere

100

This state of balance exists when the outward pressure of fusion perfectly counters the inward pull of gravity.

Hydrostatic (or Thermo-gravitational) Equilibrium

200

Stars spend about 90% of their lives in this stable phase, fusing hydrogen into helium.

Main Sequence

200

This fusion cycle is dominant in massive stars and uses Carbon, Nitrogen, and Oxygen as catalysts.

CNO cycle

200

This is the catastrophic explosion that marks the death of a massive star.

Supernova

200

These dark, cooler regions on the photosphere are caused by localized magnetic fields.

Sunspots

200

This quantum mechanical effect occurs when electrons resist being squeezed into the same volume, supporting White Dwarfs.

Electron Degeneracy

300

This is the pre-main sequence stage where a dense core of a molecular cloud collapses and begins to heat up.

Protostar

300

Once a massive star's core has fused elements up to this specific metal, it can no longer produce energy through fusion.

Iron

300

This is a region of spacetime with gravity so intense that not even light can escape.

Black Hole

300

In this layer, energy is transported by massive circulating currents, similar to a pot of boiling water.

Convection Zone

300

This type of degeneracy pressure supports the ultra dense core left behind after a Type II Supernova.

Neutron Degeneracy

400

This term describes the precise moment a star first begins stable core hydrogen fusion.

Zero-Age Main Sequence

400

Due to the "random walk" through dense layers, it can take a photon up to this long to travel from the core to the surface.

tens of thousands to over a million years

400

This is the name for the maximum mass (1.4 solar masses) a white dwarf can have before it collapses.

Chandrasekhar Limit

400

This is the star's tenuous, outermost atmosphere that is surprisingly hotter than the surface.

Corona

400

These vast, cold regions of interstellar gas and dust (mostly hydrogen) are the birthplaces of stars.

Giant Molecular Clouds

500

These are often called "failed stars" because their mass is too low (less than 0.08) to ever ignite hydrogen fusion.

Brown Dwarfs

500

Once a photon finally escapes the Sun’s surface, it takes approximately this long to reach Earth.

8.2-8.4 Seconds

500

This is a sudden, bright flare-up on a white dwarf's surface caused by accreting hydrogen from a companion star.

Nova

500

This layer surrounds the core and transports energy through the continuous absorption and re-emission of photons.

Radiation Zone

500

This thin, reddish layer of the atmosphere is typically only visible during a total solar eclipse.

Chromosphere