Besides the Sun, the Moon is the most obvious
object in the sky. Bright, silvery, with tantalizing features on its face, it’s been the
target of imagination, poetry, science, and even the occasional rocket. If you pay even the most cursory attention
to it, you’ll see that it changes every day; sometimes it’s up in the day, sometimes
at night, and its shape is always changing. What causes this behavior? The Moon is basically a giant ball of rock
3500 kilometers across hanging in space. Its surface is actually pretty dark, with about
the same reflectivity as a chalkboard or asphalt. However, it looks bright to us because it’s
sitting in full sunlight; the Sun illuminates it, and it reflects that light down to us
here on Earth. And because it’s a sphere, and orbiting
the Earth, the way we see it lit by the Sun changes with time. That’s what causes its
phases: geometry. The important thing to remember through all
this is, because the Moon is a ball and in space, half of it is always illuminated by
the Sun! This is true for the Earth, too, and every
spherical object in space; half faces the Sun, half faces away. We call the part facing
the Sun the daylight or bright side, and the half facing away the night or dark side. The phase of the Moon refers to what shape
the Moon appears to us; how much of it we see illuminated from the Earth. The key to
all this is this line, dividing the lit day side from the unlit night side. We call that
line the terminator. If you’re facing the moon, with the sun
behind you, you’re seeing the half of the moon that is fully illuminated by sunlight
and it looks full. If you’re off to the side you see half of the lit side and half
of the dark side and we say the moon is half full. If the sun is on the other side of the
moon, you’re look at the unlit half, and it looks dark. Now, mind you, I haven’t
moved anything except our point of view here, so at all times the Moon is always half lit,
and half dark. Remember that. The phase of the Moon we see depends on from
what direction the sunlight’s hitting it, and the angle we see that from Earth. The Moon orbits the Earth roughly once per
month. In fact, that’s where the word “month” comes from; “month” and “Moon” are
cognates, words that have similar etymological histories, and in most languages, including
English, the two words are very similar. The length of time we call the month is derived
from the length of time it takes the Moon to go through all its phases -- 29.5 days. So. To describe the phases, let’s start
at the beginning: New Moon. New Moon happens when the Sun, Moon, and Earth
are all more or less in a line. The Moon’s orbit is actually tipped a bit to the Earth’s,
so sometimes new Moon happens when the Moon is “below” the Sun, or “above” it.
But at some point in its orbit, at some point in the month, it appears to be as close to
the Sun as it can. What does this look like from Earth? The Moon is between the Earth and the Sun,
so from our perspective we only see the dark half, the unilluminated half, of the Moon.
The other side, the far side, of the Moon is lit, but we can’t see it. It makes sense
then to call this the beginning of the Moon’s cycle, hence the term “New Moon”. Now think about this for a sec: Because the
Moon is near the Sun in the sky, it travels across the sky with the Sun. It’s up during
the day! You can only see it from the part of the Earth that’s lit, which is when it’s
daytime. It’s a very common misconception that the Moon is only up at night, but it’s
up during the day literally just as often. At New Moon, the Moon stays near the Sun,
so it rises at sunrise, and sets at sunset. This makes it extremely difficult to see;
it is, after all, sitting next to the brightest object in the sky, and only a little bit of
it is lit from our perspective. But not for long. Because the Moon is orbiting
the Earth, after a couple of days it’s moved a bit to the east. Now we’re seeing it along
a slight angle, and we can see a little bit of the illuminated half of the Moon on its
side toward the Sun. The terminator, the day/night line, appears
curved around the Moon, so what we see is a thin illuminated crescent Moon. At this
point the crescent is still very thin, with the horns of the crescent pointing away from
the Sun. Note that the Moon is still pretty close to
the Sun in the sky, just a bit to the east, rising maybe an hour or two after sunrise.
But this means it’s up all day, and then sets after the Sun does. This is the best
time to see the crescent Moon, when the Sun has already set and the sky starts to get
dark. The Moon will be low over the western horizon, and it will set soon after the Sun
does. Let’s wait a couple of days. OK, now the Moon has moved a bit more in its
orbit around the Earth, and is farther from the Sun in the sky. We see a little more of
the illuminated part, and the crescent is wider. Since it’s getting thicker, we say
this is a “waxing crescent” Moon; waxing means growing or getting bigger. It’s also
well away from the Sun now, so it’s easier to spot, even during the day before sunset. Seven or so days after new Moon we get to
our first milestone: the Moon is now one-quarter of the way around its orbit. It’s 90° away
from the Sun in the sky, which means we’re looking straight down on the terminator, the
Moon’s day/night line. It cuts right down the middle of the visible face of the Moon,
so it’s half lit, with the sunward side of the Moon visible and the other side dark. Confusingly, this phase is properly named
“first quarter” because the Moon is ¼ of the way through its cycle, ¼ of the way
through its orbit around the Earth, even though it looks half full. So it’s not really the
half-full moon -- astronomers prefer “first quarter,” so if you want to sound all astronomery,
then you should call it that. But time marches on. The Moon continues on
its gravitational dance with Earth, swinging around its orbit. Now more than half full,
we say its shape is “gibbous”, which means swollen or convex. Since it’s getting wider,
this is actually the waxing gibbous phase of the Moon. It rises in the late afternoon,
and is up most of the night. Our next big step comes two weeks after new
Moon, when it’s moved halfway through its orbit. It is now opposite the Sun in the sky,
180° around. The Earth is between the Moon and Sun, so we’re looking at the fully-illuminated
half of the Moon. This is the full Moon. Because it’s opposite the Sun, it rises
at sunset and sets and sunrise; it’s up all night shining down on the Earth. But again, wait a couple of days and things
change. When the Moon is full it’s 180° around the sky from the Sun, so as it continues
to move around the Earth in a circle the distance between it and the Sun is now starting to
decrease, even as it continues on in the same direction. As before, it keeps rising and
setting later, but now it rises after sunset, and sets after sunrise. If you get up early
in the morning as the Sun is just rising in the east, you’ll see the nearly-but-not-quite
full Moon setting in the west. Not only that, but we’re about to go through
all the phases again, but in reverse order. A few days after full Moon the lit side is
shrinking. It’s in the waning, or shrinking, gibbous phase. Then, three weeks or so after new Moon, and
a week after full, the Moon is once again half lit, the terminator splitting the Moon’s
face in two even halves. This is the “third quarter” Moon, because the Moon is ¾ of
the way through its cycle. It’s a lot like the first quarter, but the side that was lit
is now dark, and vice versa. It’s 270° around the sky from the Sun. It rises at midnight
and sets at noon. A few days later and the Moon is a crescent
again, getting thinner. It’s now a “waning crescent.” It rises just a couple of hours
before sunrise, and sets a couple of hours before sunset. Then, finally, we’re back where we started.
One month after new Moon, the Moon has traveled 360° around the sky, and is once again as
close to the Sun as it can get. It’s new Moon, and the cycle starts up again as it
has for time immemorial. An interesting thing happens if you move your
perspective from the Earth to the Moon. The phases of the Moon we see from Earth depend
on the angle of the Moon and Sun in the sky. But on the Moon, the angles are exactly 180°
reversed; at new Moon, when the Moon is between the Earth and Sun, the Earth
is opposite the Sun as seen from the Moon. It’s full Earth! All the other phases are opposite too, so
when we see a full Moon, a Moon-dweller would see a new Earth, and so on. Have you ever looked at the thin crescent
Moon and seen the ghostly face of the rest of the unlit side? That’s because it’s
not really unlit: the nearly full Earth is reflecting sunlight on the Moon, lighting
up the otherwise dark part. The Earth is bigger and more reflective than
the Moon, so it’s actually 50 times brighter than a full Moon! This glow is called Earthshine,
a term I quite like. Even more poetically, it’s been called “the old Moon in the
new Moon’s arms”, referring to the unlit part surrounded by the crescent new Moon’s
horns. That’s lovely, isn’t it? The Moon is one of the most beautiful and
most gratifying objects in the sky to observe. It’s different every day! Yet it’s also
the same, because we see, more or less, the same half of it, the same face all the time.
It’s big and bright, and the features on its surface discernible by eye (and even better
with binoculars or a small telescope). As the phases change, inexorably, day after
day, the angle of sunlight hitting the surface changes, bringing new things into our view.
The motions become comforting, even familiar. It’s a reminder that the Universe may seem
strange and complicated and forbidding at first, but over time, as you get outside and
experience it, it becomes your neighborhood. Welcome home. Today you learned why the Moon has phases:
It’s a sphere, and it orbits the Earth, so the angle at which we see its lit side
changes. It goes from new, to waxing crescent, to half full, waxing gibbous, full, waning
gibbous, half full, waning crescent, and then the cycle starts all over again. This also
affects when it rises and sets, and what we see on the surface. Crash Course is produced in association with
PBS Digital Studios. This episode was written by me, Phil Plait. The script was edited by
Blake de Pastino, and our consultant is Dr. Michelle Thaller. It was co-directed by Nicholas
Jenkins and Michael Aranda, and the graphics team is Thought Café.
I knew there would be a terminator joke haha
Nice. It seems to be directed towards absolute beginners with zero observing experience whatsoever, but the information is delivered in an interesting and well thought out way.