Information AboutPrecession Of The Equinoxes |
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PRECESSION The Earth goes through one complete Precession cycle in a period of approximately 25,800 years, during which the positions of Star s as measured in the Equatorial Coordinate System slowly change. The change in celestial coordinates in relation to earth's topographic coordinates is due to the rotation of the earth's inclined axis of rotation in space, a retrograde motion in relation to orbit direction. As a result, the year is shorter than solar orbit by the inverse of the precession period. A year is complete when the axis of rotation returns to the same direction in relation to the sun. Over the precession cycle, the Earth's north axial pole moves from where it is now pointing, within 1° of Polaris , in a circle around the Ecliptic Pole , with a current angular radius of 23 degrees 27 arcminutes , or about 23.5 degrees. The shift is 1 degree in 180 years (the angle is taken from the observer, not from the center of the circle). The explanation of this is: The axis of the Earth undergoes precession due to a combination of the Earth's nonspherical shape (it is an Oblate Spheroid , bulging outward at the equator) and the gravitational tidal forces of the Moon and Sun applying torque as they attempt to pull the Equatorial Bulge into the plane of the Ecliptic . The portion of the precession due to the combined action of the Sun and the Moon is called lunisolar precession. A changing north star Polaris is not particularly well-suited for marking the north celestial Pole , as its visual magnitude, which is variable, hovers around 2.1, fairly far down the list of brightest stars in the sky. On the other hand, in 3000 BC the faint star Thuban in the Constellation Draco was the Pole Star ; at magnitude 3.67 it is only one-fifth as bright as Polaris; today it is all but invisible in light-polluted urban skies. The brightest star known to have been North Star or to be predictable as taking that role in the future is the brilliant Vega in the constellation Lyra , which was the pole star around 12000 BC and will be again around the year AD 14,000. When viewed looking down onto the Earth from the north, the direction of precession is clockwise. When standing on Earth looking outward, the axis appears to move counter-clockwise across the sky. This sense of precession, against the sense of Earth's own axial rotation, is opposite to the precession of a top on a table. The reason is that the Torque s imposed on the Earth by the Sun and Moon act in the sense of trying to align its axis normal to the Ecliptic , i.e. to stand up more vertically in regard to the ecliptic plane, while the Torque on a top spinning on a hard surface acts in the sense of trying to make the top fall over, rather than to stand up straighter. Polaris is not exactly at the pole; any long- Exposure unguided photo will show it having a short trail. It is close enough for most practical purposes, though. The south celestial pole precesses too, always remaining exactly opposite the north pole. The south pole is in a particularly bland portion of the sky, and the nominal south pole star is Sigma Octantis , which, while fairly close to the pole, is even weaker than Thuban -- magnitude 5.5, which is barely visible even under a properly dark sky. The precession of the Earth is not entirely regular due to the fact that the Sun and Moon are not in the same plane and move relative to each other, causing the torque they apply to Earth to vary. This varying torque produces a slight irregular motion in the poles called Nutation . Precession of the Earth's axis is a very slow effect, but at the level of accuracy at which astronomers work, it does need to be taken into account. Note that precession has no effect on the inclination ("tilt") of the plane of the Earth's equator (and thus its axis of rotation) on its orbital plane. It is 23.5 degrees and precession does not change that. The inclination of the equator and rotation axis in relation to the ecliptic (solar orbit) does change due to gravitational torque, but its period is different (main period about 41000 years). This figure illustrates the effects of axial precession on the seasons, relative to Perihelion and Aphelion . The precession of the equinoxes can cause periodic Climate Change (see Milankovitch Cycles ), because the hemisphere that experiences summer at perihelion and winter at aphelion (as the southern hemisphere does presently) is in principle prone to more severe seasons than the opposite hemisphere. Hipparchus estimated Earth's precession around 130 BC , adding his own observations to those of Babylonia n and Chaldea n astronomers in the preceding centuries. In particular they measured the distance of the Star s like Spica to the Moon and Sun at the time of Lunar Eclipse s, and because he could compute the distance of the Moon and Sun from the equinox at these moments, he noticed that Spica and other stars appeared to have moved over the centuries. Precession causes the cycle of seasons ( Tropical Year ) to be about 20.4 minutes less than the period for the earth to return to the same position with respect to the stars as one year previously ( Sidereal Year ). This results in a slow change (one day per 71 calendar years) in the position of the sun with respect to the stars at an Equinox . It is significant for Calendar s and their Leap Year rules. |
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