• The Day That Doesn't Exist- Decoding the Myth and Magic of Leap Year

  • 2024/02/28
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The Day That Doesn't Exist- Decoding the Myth and Magic of Leap Year

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  • The concept of Leap Year and Leap Day has existed for over 2000 years, with the extra day added to our calendars in February every four years to account for the fact that the actual length of a year does not perfectly align to the 365 days of our modern Gregorian calendar. This misalignment means calendar dates would slowly drift from their intended seasons if no adjustment was made over time. In this article, we will explore the science behind Earth’s actual orbit around the sun and rotation on its axis that necessitates the need for a Leap Year. We will detail the history of previous inaccurate calendars, how the modern Leap Year system was created, and some alternative solutions that have been suggested instead of our current traditional method of handling the extra quarter day each solar orbit. The Science Behind Earth’s Orbit and Rotation The need for Leap Years originates from a differential between two astronomical time spans - the sidereal year and the tropical year. A sidereal year refers to the time it takes the Earth to orbit the sun once relative to the fixed stars: approximately 365.25636 days. Over this orbital period, Earth’s position relative to the stars shifts slightly each day. In contrast, the tropical year is measured between successive vernal (spring) equinoxes as Earth moves through its seasons: lasting roughly 365.24219 days. Each equinox lands Earth at the same place relative to its tilted axis and orbit around the sun rather than the fixed stars. This tropical year dictates the actual seasons and calendar dates we experience on a yearly cycle. The ~20-minute difference between a sidereal and tropical year may seem insignificant, but it adds up over time when relying on consistent seasons and calendar years. Even this small differential means a typical 365-day calendar would become noticeably misaligned after just a few decades. Early Attempts At Accurate Calendars Humans have long understood the concept of a year’s length not precisely lining up with a whole number of days. Ancient Babylonian astronomers estimated the tropical year as 365.2467 days. They aimed to balance their 12 months of either 29 or 30 days through the addition of an extra 13th leap month called an intercalary month about every three years. But this method still resulted in the gradual drifting of seasons over decades. The first major attempt to settle on a more accurate tracking of days and years came with the implementation of the Julian Calendar in Rome in 45 BC under Julius Caesar. It featured a standard year of 365 days with an extra day added to February every four years going forward. This aligned much closer to the tropical year by averaging out to 365.25 days when factoring in leap years. It also locked in dates of the winter solstice to December 25th and the spring equinox to March 25th. The Julian Calendar served much of Europe and the Western world well for over 1500 years. It maintained equinox and solstice date alignment within a day into the mid-1500s. But those small errors still had added up by then, motiving Pope Gregory XIII to assemble top astronomers to develop an improved and more lasting solution. The Creation of the Modern Gregorian Calendar After the Council of Trent authorized Pope Gregory XIII to reform the calendar in 1582, astronomers proposed the Gregorian Calendar of the same year to better achieve synchronization with the tropical year. By skipping 10 days to realign the spring equinox date and also modifying the leap year rules slightly, the Gregorian Calendar resulted in a more accurate system expected to keep seasons on track within a day for the next 3300 years. The new Gregorian Calendar leap year rules specify that years divisible by 100 are not leap years unless they are also divisible by 400. So years like 1700, 1800 and 1900 do not have a February 29th while 1600 and 2000 are considered leap years. This exception brings the average length of the Gregorian Calendar up from 365.25 days as in the Julian Calendar to 365.2425 days. Since the tropical year is now calculated as precisely 365.24219 days long, this minimum error should maintain seasonal date alignment well into the distant future. Countries were slow to adopt the Gregorian Calendar after its 1582 debut however. It took over 360 years for it’s use to extend around the globe. The important 1752 British adoption also necessitated dropping 11 days in September to realign - leading to riots from people believing precious days of their lives were being taken by the government. Most Eastern Orthodox countries only switched from the Julian Calendar in the early 20th century. How Leap Days Function In both the Julian and Gregorian Calendars, the extra Leap Day is added onto the shortest month of February once every four years. This keeps the numbering alignment stable across other months while making the length of February also more comparable from standard years to leap years. Having all standard years be ...
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あらすじ・解説

The concept of Leap Year and Leap Day has existed for over 2000 years, with the extra day added to our calendars in February every four years to account for the fact that the actual length of a year does not perfectly align to the 365 days of our modern Gregorian calendar. This misalignment means calendar dates would slowly drift from their intended seasons if no adjustment was made over time. In this article, we will explore the science behind Earth’s actual orbit around the sun and rotation on its axis that necessitates the need for a Leap Year. We will detail the history of previous inaccurate calendars, how the modern Leap Year system was created, and some alternative solutions that have been suggested instead of our current traditional method of handling the extra quarter day each solar orbit. The Science Behind Earth’s Orbit and Rotation The need for Leap Years originates from a differential between two astronomical time spans - the sidereal year and the tropical year. A sidereal year refers to the time it takes the Earth to orbit the sun once relative to the fixed stars: approximately 365.25636 days. Over this orbital period, Earth’s position relative to the stars shifts slightly each day. In contrast, the tropical year is measured between successive vernal (spring) equinoxes as Earth moves through its seasons: lasting roughly 365.24219 days. Each equinox lands Earth at the same place relative to its tilted axis and orbit around the sun rather than the fixed stars. This tropical year dictates the actual seasons and calendar dates we experience on a yearly cycle. The ~20-minute difference between a sidereal and tropical year may seem insignificant, but it adds up over time when relying on consistent seasons and calendar years. Even this small differential means a typical 365-day calendar would become noticeably misaligned after just a few decades. Early Attempts At Accurate Calendars Humans have long understood the concept of a year’s length not precisely lining up with a whole number of days. Ancient Babylonian astronomers estimated the tropical year as 365.2467 days. They aimed to balance their 12 months of either 29 or 30 days through the addition of an extra 13th leap month called an intercalary month about every three years. But this method still resulted in the gradual drifting of seasons over decades. The first major attempt to settle on a more accurate tracking of days and years came with the implementation of the Julian Calendar in Rome in 45 BC under Julius Caesar. It featured a standard year of 365 days with an extra day added to February every four years going forward. This aligned much closer to the tropical year by averaging out to 365.25 days when factoring in leap years. It also locked in dates of the winter solstice to December 25th and the spring equinox to March 25th. The Julian Calendar served much of Europe and the Western world well for over 1500 years. It maintained equinox and solstice date alignment within a day into the mid-1500s. But those small errors still had added up by then, motiving Pope Gregory XIII to assemble top astronomers to develop an improved and more lasting solution. The Creation of the Modern Gregorian Calendar After the Council of Trent authorized Pope Gregory XIII to reform the calendar in 1582, astronomers proposed the Gregorian Calendar of the same year to better achieve synchronization with the tropical year. By skipping 10 days to realign the spring equinox date and also modifying the leap year rules slightly, the Gregorian Calendar resulted in a more accurate system expected to keep seasons on track within a day for the next 3300 years. The new Gregorian Calendar leap year rules specify that years divisible by 100 are not leap years unless they are also divisible by 400. So years like 1700, 1800 and 1900 do not have a February 29th while 1600 and 2000 are considered leap years. This exception brings the average length of the Gregorian Calendar up from 365.25 days as in the Julian Calendar to 365.2425 days. Since the tropical year is now calculated as precisely 365.24219 days long, this minimum error should maintain seasonal date alignment well into the distant future. Countries were slow to adopt the Gregorian Calendar after its 1582 debut however. It took over 360 years for it’s use to extend around the globe. The important 1752 British adoption also necessitated dropping 11 days in September to realign - leading to riots from people believing precious days of their lives were being taken by the government. Most Eastern Orthodox countries only switched from the Julian Calendar in the early 20th century. How Leap Days Function In both the Julian and Gregorian Calendars, the extra Leap Day is added onto the shortest month of February once every four years. This keeps the numbering alignment stable across other months while making the length of February also more comparable from standard years to leap years. Having all standard years be ...

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