With July of this year, 2023, being the hottest on Earth yet recorded, there are increasing concerns about how climate change will shape the next several decades. We often hear about how climate change will increase disastrous weather events, decimate crops, and...
2020 is a leap year. Don’t forget! In 2020, we will have 366 days instead of our usual 365, giving us the enigmatic February 29th. Didn’t we just have a leap year in 2016? Why do we have leap years at all?
We add a leap day to the calendar every four years (except for a few exceptions) because of an eternal conflict between the true astronomical year and the calendar that we follow, the Gregorian Calendar.
An astronomical year is the time it takes for the Earth to make one complete revolution around the sun. Surprise! And although it’s pretty close, our calendar year doesn’t quite match up to it.
While our calendars tell us that the year is a neat 365 days long, in reality, our year is actually about 365 days and six hours, or about 365.25 days, long. This makes keeping track of time a bit tricky, and we use leap days to keep our calendar year as close to the astronomical year as we can.
Because our calendar year is about six hours shorter than our astronomical year, we start celebrating the new year earlier and earlier every year. In other words, after 365 days have rolled around, our planet hasn’t quite reached the location it was in at the same time last year.
Because the astronomical year is about six hours (a quarter of a day) longer than our calendar year, the lost time accounts for about a day per every four years. To make up for this lag, we add a day to the calendar every four years. Adding an extra day to the calendar every four years brings us pretty close, on average, to the location in space that we occupied one calendar year ago, which would make our calendar match the true astronomical year.
However, the story does not end there.
Things get a bit more complicated once we take into account the fact that the astronomical year is not exactly 365 days and six hours long. In fact, the astronomical year is actually 365 days, five hours, 48 minutes and 45 seconds, or 365.2422 days long. This means that by adding an average of six hours to the calendar every year, we are actually overshooting the astronomical year by 11 minutes and 15 seconds. These extra minutes might not seem like a big deal year-to-year, but over the course of 400 years, these added minutes add up to about three extra days. To compensate for these extra days, we remove three leap days from the calendar every 400 years. To do this, we don’t pull random leap days from the calendar; instead, we take away the leap days that occur on century years that are not divisible by 400. For example, we had a leap year in 2000, and we will again in 2400, but we will not have a leap year in 2100, 2200, or 2300.
The way our leap day schedule is set up, we come pretty close to matching the true astronomical year, but it’s not perfect. We are so close, though, that whatever differences are left are so small that they do not affect us. If you really want to get nit-picky, though, keep reading.
On December 31st, 2016, scientists added time to the calendar, but you probably didn’t notice. Why? They added a leap second to the calendar. That day, instead of going from 23:59:59 on December 31st to 00:00:00 on January 1st, we went to 23:59:60 just before January began.
Scientists occasionally add a second to the year bring our day closer in line with the astronomical day. Similar to the astronomical year, the astronomical day is not exactly 24 hours, so we have to make adjustments to keep us on schedule. Unlike Earth’s revolution around the sun (which gives us our years), Earth’s rotation around its axis (which gives us our days) varies a lot and cannot be predicted. Therefore, scientists do not know when they will need to add a leap second to the year until a few months before it happens. Leap seconds are not added on any regular schedule, and only 27 leap seconds have been added since we started keeping track of the astronomical day in 1972. Leap seconds have brought on a huge amount of controversy in the computing community, because adding seconds at random times makes it much more difficult to time events accurately.
Leap years and leap seconds occur because our calendars do not align with what is actually happening in space. Astronomers keep careful track of where our Earth is relative to the sun, and where we are in our daily rotation, so that the rest of us don’t have to. Can you imagine if we had to use a calendar that was 365 days, four hours, 48 minutes, and 15 seconds long? What if we had to observe a day that was a few seconds over or under 24 hours? While our 365 day year and 24 hour day are not perfect from a scientific point of view, they get the job done for most of us, and we can rest assured that astronomers will keep us on schedule.
The Gregorian Calendar is not the most accurate calendar out there. Mathematicians agree that the most accurate calendar ever designed was the Jalali (or Persian) Calendar, which approximates the year to a much more accurate length than the Gregorian Calendar. You can read about the Jalil Calendar, and how it was designed, here.
Note: This article has been updated to reference 2020 and the 2016 leap second.