Star Color

Stellar Vortex Quality is revealed by its color as its surface temperature.

• Blue stars are the hottest (above 30,000°F / 16,000°C).
• White stars are very hot (10,000°F – 30,000°F / 5,500°C – 16,000°C).
• Yellow stars are moderately warm (9,000°F – 10,000°F / 5,000°C – 5,500°C).
• Orange stars are cool (7,000°F – 9,000°F / 3,500°C – 5,000°C).
• Red stars are the coolest (below 7,000°F / 3,500°C).

Most stars are red or having a weak spin.

Why So Many Red Dwarfs?

The galaxy is overwhelmingly red. Over seven out of every ten stars are red dwarfs—small, cool, and incredibly stingy with their fuel.

They burn so slowly that a single red dwarf can outlive the current age of the universe. Their faintness is why you cannot see them with the naked eye; not a single red dwarf is visible from Earth without a telescope.

Blue stars, by contrast, are rare showoffs. Though they dominate the constellations we recognize (like Orion’s Rigel or Spica in Virgo), they make up barely 2% of all stars. They burn hot, fast, and die young in spectacular supernovae.

Why are there no Green Stars?

In our MSQ Model, Green is the middle of red green blue. But with stars, this is replaced by white which is a combination of all colors, in accordance with temperature.

In other words:

• white stars are white instead of green because star colors come from the spin of heat particles
• green LED is green instead of white because LED colors come from electron spin

By exapnding Descartes Physics, we can say that:

• white stars are white instead of green because star colors come from the spin of heat particles
• green LED is green instead of white because LED colors come from electron spin from jumping the band gap.

This is consistent with green flames being caused by electrons such as those in copper, as used in fireworks.

Both lightning and arc welding use electrons but also have high heat which then produces the white light.