Flask model of the Pythagorean system
Using the celestial sphere apparatus to model the Pythagorean system.
Apparatus and materials
Polystyrene sphere, small
Celestial sphere apparatus as used in the 'Model of the Celestial sphere' experiment
Yellow Sun disk
Health & Safety and Technical notes
Take normal care with glassware. Keep the model out of sunlight as flask and water can act as a convex lens and produce localised heating.
Mount the polystyrene sphere on the needle and insert it through the bung into the flask which is half full of water. Adjust the position of the sphere and the volume of water so that the sphere is at the centre of the flask and in the water surface when the flask is inverted. The sphere represents the Earth.
Invert the whole assembly and place it in a ring on a tripod or attach it to a retort stand. Mark the ecliptic on the flask with a pen or a band of coloured tape (at 23 1/2° to the equatorial plane of the model). Temporarily stick a yellow disc to represent the Sun at various points on the ecliptic.
Show the daily motion of the heavens by rotating the flask about its own axis. Show the progress of the Sun through the seasons of the year by moving it from place to place round the ecliptic whilst the flask is spun for each position.
1 (See guidance note Early astronomical observations).
2 Pythagoras (about 530 BC) developed a more complex model than Thales' model. The Pythagorian School accepted that the Earth was a sphere. The stars and planets were imagined to sit on an imagined scheme of concentric spheres, like shells of an onion, the 'Crystal Spheres'. The outermost spheres carried the stars with the daily motion. Inside were other spheres, each carrying a planet. Starting from the outermost, they were in this order:
In later stages, this model of celestial spheres had all the inner spheres attached to the outermost one, which carried them round with the 24-hour motion. Then the Sun's sphere revolved backwards once a year about an axis on the ecliptic. The spheres for the Moon and other planets all revolved slowly backwards about the same axis; one revolution a month for the Moon; one revolution in 12 years for Jupiter.
This model imitated the motions of the Sun and Moon fairly well but gave only the general motions of the planets, without their retrograde loops.
This experiment was safety-checked in April 2007