Eclipse
Eclipse->> FREQUENCY OF ECLIPSES
If the earth’s orbit, or the ecliptic, were in the same plane as the moon’s orbit, two total eclipses would occur during each lunar month, a lunar eclipse at the time of each full moon, and a solar eclipse at the time of each new moon. The two orbits, however, are inclined, and, as a result, eclipses occur only when the moon or the sun is within a few degrees of the two points, called the nodes, where the orbits intersect.
Periodically both the sun and the moon return to the same position relative to one of the nodes, with the result that eclipses recur at regular intervals. The time of the interval, called the saros, is a little more than 6585.3 days or about 18 years, 9 to 11 days, depending on the number of intervening leap years, and 8 hours. The saros, known since the time of ancient Babylonia, corresponds almost exactly to 19 returns of the sun to the same node, 242 returns of the moon to the same node, and 223 lunar months. The disparity between the number of returns of the moon and the number of lunar months is the result of the nodes moving westward at the rate of 19.5° per year. An eclipse that recurs after the saros will be a duplicate of the earlier eclipse but will be visible 120° farther west on the earth’s surface, because of the rotation of the earth during the third of a day included in the interval. Lunar eclipses recur 48 or 49 times and solar eclipses 68 to 75 times before slight differences in the motions of the sun and moon eliminate the eclipse.
During one saros about 70 eclipses take place, usually 29 lunar and 41 solar; of the latter, usually 10 are total and 31 partial. The minimum number of eclipses that can occur in a given saros year is 2, the maximum 7, and the average is 4.
During the 20th century 375 eclipses took place: 228 solar and 147 lunar. The last total eclipse of the sun visible in the United States occurred over the state of Hawaii on July 11, 1991. The prior such eclipse occurred over the state of Washington on February 26, 1979. The next total eclipse will be visible from the U.S. in 2017.
If the earth’s orbit, or the ecliptic, were in the same plane as the moon’s orbit, two total eclipses would occur during each lunar month, a lunar eclipse at the time of each full moon, and a solar eclipse at the time of each new moon. The two orbits, however, are inclined, and, as a result, eclipses occur only when the moon or the sun is within a few degrees of the two points, called the nodes, where the orbits intersect.
Periodically both the sun and the moon return to the same position relative to one of the nodes, with the result that eclipses recur at regular intervals. The time of the interval, called the saros, is a little more than 6585.3 days or about 18 years, 9 to 11 days, depending on the number of intervening leap years, and 8 hours. The saros, known since the time of ancient Babylonia, corresponds almost exactly to 19 returns of the sun to the same node, 242 returns of the moon to the same node, and 223 lunar months. The disparity between the number of returns of the moon and the number of lunar months is the result of the nodes moving westward at the rate of 19.5° per year. An eclipse that recurs after the saros will be a duplicate of the earlier eclipse but will be visible 120° farther west on the earth’s surface, because of the rotation of the earth during the third of a day included in the interval. Lunar eclipses recur 48 or 49 times and solar eclipses 68 to 75 times before slight differences in the motions of the sun and moon eliminate the eclipse.
During one saros about 70 eclipses take place, usually 29 lunar and 41 solar; of the latter, usually 10 are total and 31 partial. The minimum number of eclipses that can occur in a given saros year is 2, the maximum 7, and the average is 4.
During the 20th century 375 eclipses took place: 228 solar and 147 lunar. The last total eclipse of the sun visible in the United States occurred over the state of Hawaii on July 11, 1991. The prior such eclipse occurred over the state of Washington on February 26, 1979. The next total eclipse will be visible from the U.S. in 2017.
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