Total solar eclipse 2024: The moon's moment in the sun

On April 8, 2024, much of North America will experience a solar eclipse: a cosmic alignment of sun, moon, and Earth, in that order. The moon's shadow path will make landfall on Mexico's Pacific coast, cross the United States from Texas to Maine, and exit North America via Newfoundland, Canada, continuing into the Atlantic Ocean.

Solar eclipses on Earth are a convenient coincidence. The sun's diameter is about 400 times larger than the moon's, and the sun is almost 400 times farther away from us than the moon is. This combination makes the sun and moon appear nearly the same size in our sky, setting up a spectacular show when they align. Try experimenting with apparent size for yourself by holding up a small item, like your thumb, and moving it closer and farther away to block different-sized objects from your view.

The moon's distance from Earth varies, though only slightly. The moon's orbit is not a perfect circle, and it is not quite centered on our planet. At its closest, the moon is about twenty-eight Earth diameters away; at its farthest, about thirty-two. As a result, the moon's apparent size changes over time, and eclipses are not all alike.

A total solar eclipse is only possible when the moon is closer to Earth than average. When the moon is farther away, its apparent size is smaller than the sun's, so it does not completely block the sun's bright disk. In this configuration, when the moon passes between Earth and the sun, a "ring of fire" remains visible—that's an annular solar eclipse.

An orbital dance

Ever wonder why solar eclipses don't happen more often? Earth, moon, and sun don't line up perfectly every month because the moon's orbit is tilted by about 5 degrees compared to Earth's orbit around the sun. Most of the time, the moon's shadow misses our planet.

When all three celestial bodies do align, views of the eclipse depend not just on our position in the solar system, but also on our location on Earth. The moon's shadow has two parts, the umbra and the penumbra. Observers in the umbra (or "path of totality") will experience a total solar eclipse. For those in the penumbra, the eclipse will be partial.

If you are planning to observe the eclipse, you've probably consulted a shadow path map like the one above. But how do we know exactly where and when the moon will cast its shadow? Eclipse prediction depends, first and foremost, on understanding the positions and movements of the moon, sun, and Earth. Modern maps build on a long human history of eclipse forecasting. And since 2009, NASA's Lunar Reconnaissance Orbiter (LRO) has been mapping the moon in unprecedented detail. LRO's lunar topography data enables us to make more accurate eclipse predictions than ever before.

Moonshadow: The making of a map

The moon is a rugged world of peaks, craters, basins, and valleys. Since the lunar horizon is bumpy and jagged, the shadow it casts is not quite round. Knowing the precise shape of the moon helps us understand exactly where its shadow will darken Earth's surface.

Of course, our own planet is not perfectly round, either. Today's eclipse maps account not only for the lunar landscape, but also for the contours of Earth's mountain ranges, lowlands, and other features.

Bursts of light: Baily's Beads and the Diamond Ring Effect

Casual observers don't usually notice that the moon's silhouette is rough around the edges. At a distance of 239,000 miles (that's the average gap between Earth and the moon), our nearest neighbor in space looks round—even mountains appear too small for the human eye to distinguish. But, for two brief moments during a solar eclipse, craggy lunar terrain commands the spotlight.

On the brink of totality, as the moon moves into full sun-blocking position, the sun's edge doesn't go dark all at once. Last rays of sunlight peek through valleys on the lunar horizon. These isolated areas of intense brightness can resemble a string of glowing beads or a single dramatic burst of light like the gem on a ring. The same phenomena, sometimes called Baily's Beads and the Diamond Ring Effect, can also occur as the moon edges out of totality (or annularity). Since we know the shape and position of the moon so well, we can predict where the first and last bits of sunlight will appear.