Total Lunar Eclipse Sequence
A composite of seven images shows the full moon at perigee, or supermoon, during a total lunar eclipse on Sunday, Sept. 27, 2015, in Denver. Credit: NASA/Bill Ingalls

During a lunar eclipse, Earth comes between the Sun and the Moon, blocking the sunlight falling on the Moon.

There are two kinds of lunar eclipses:

  • A total lunar eclipse occurs when the Moon and Sun are on opposite sides of Earth.
  • A partial lunar eclipse happens when only part of Earth's shadow covers the Moon.

During some stages of a lunar eclipse, the Moon can appear reddish. This is because the only remaining sunlight reaching the Moon at that point is from around the edges of the Earth, as seen from the Moon's surface. From there, an observer during an eclipse would see all Earth's sunrises and sunsets at once.

​The next lunar eclipse that can be seen all over the U.S. will be on Jan. 21, 2019. It will also be a supermoon.

The next lunar eclipse that can be seen all over the U.S. will be on Jan. 21, 2019. It will also be a supermoon.

It's not often that we get a chance to see our planet's shadow, but a lunar eclipse gives us a fleeting glimpse. During these rare events, the full Moon rapidly darkens and then glows red as it enters the Earth's shadow. More details and download options

Understanding Lunar Eclipses

A lunar eclipse occurs when the Moon passes through the Earth's shadow, just as a solar eclipse occurs when part of the Earth passes through the Moon's shadow.

So why don't eclipses happen twice a month?

The reason is that the Moon's orbit around the Earth is tilted relative to the Earth's orbit around the Sun.

But if that's the case, why do eclipses happen at all?

Throughout the year, the Moon's orbital tilt remains fixed with respect to the stars, meaning that it changes with respect to the Sun. About twice a year, this puts the Moon in just the right position to pass through the Earth's shadow, causing a lunar eclipse.

As the Moon passes into the central part of the Earth's shadow, called the umbra, it darkens dramatically. Once it's entirely within the umbra, the Moon appears a dim red due to sunlight scattered through the Earth's atmosphere.

In fact, if you watched the eclipse from the surface of the Moon, you'd see the Sun set behind the entire Earth, bathing you in a warm red glow. Back home, you'll have to stay up late to watch a lunar eclipse, but if you do you'll see the Moon in rare form, and you'll catch a brief glimpse of our own planet's long shadow.

Photograph the Moon

Capturing the Moon with a camera is one of the most satisfying—and challenging—projects available to an outdoor photographer. Here are four suggestions for making the most of a moonlit night with your camera.

Lunar Eclipses and Spacecraft

Lunar eclipses can be a science boon and engineering challenge for orbiting spacecraft, such as NASA's Lunar Reconnaissance Orbiter. The solar-powered orbiter also falls in Earth's shadow, cutting it off from the source of its power. Mission controllers shut down most instruments to conserve energy.

The team leaves on one instrument—called Diviner—that can watch how the lunar surface responds to the rapid change in temperature caused by a lunar eclipse. The data helps scientists better understand the composition and properties of the surface.

Eclipse Videos

Eclipse Activities

  • How to watch an eclipse and get students observing the Moon
  • Evaluating a Lunar Eclipse (Grades 3-12) - Students use the Danjon Scale of Lunar Eclipse Brightness to illustrate the range of colors and brightness the Moon can take on during a total lunar eclipse.
  • Observing the Moon (Grades K-6) - Students identify the Moon’s location in the sky and record their observations in a journal over the course of the moon-phase cycle.
  • Moon Phases (Grades 1-6) - Students learn about the phases of the Moon by acting them out. In 30 minutes, they will act out one complete, 30-day, Moon cycle.
  • Measuring the Supermoon (Grades 5-12) - Students take measurements of the Moon during its full phase over multiple Moon cycles to compare and contrast results.
  • Modeling the Earth-Moon System (Grades 6-8) – Students learn about scale models and distance by creating a classroom-size Earth-Moon system.
  • Make a Moon Phases Calendar and Calculator – Like a decoder wheel for the Moon, this calendar will show you where and when to see the Moon and every moon phase throughout the year!

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