Hey it’s Professor Dave, let’s check out
the night sky.
It’s taken almost ten billion years, but
we’ve finally made it.
We started with the Big Bang, we watched atoms
form, we saw these collect to form stars and
galaxies, we saw those stars explode to disperse
the materials that would become all the planets,
and we watched our own solar system form,
including the planet Earth.
Thus begins a new chapter of the story.
Upon this Earth, biomolecules arose, polymerized,
and became contained in cell membranes.
Life was born, which slowly evolved, and eventually
brought about human beings like you and me.
This fascinating chapter of the story is told
by the fields of general chemistry, organic
chemistry, biochemistry, and biology.
Check out my tutorials on those subjects if
you want to know more about that whole show,
since it’s more than a little involved,
as one might imagine, but otherwise, to get
back to astronomy, once human beings were
thinking and talking and forming civilizations,
they started to look up at the sky and wonder
together about all the things we’ve been
talking about so far.
Stars, planets, and the penetratingly deep,
dark cosmos.
What did they think about all this?
How did they begin to figure out all of these
things?
Let’s take a moment now to see what they
saw, and try to make sense of their thoughts.
Early civilizations saw a night sky that was
virtually the same as the one we see today,
or at least the one we can see from a rural
location, far away from all the smog and light
pollution found in a large city.
Objects have shifted their positions slightly,
but apart from that, our ancestors saw thousands
of stars that seemed to be fixed on some celestial
dome or sphere, slowly rotating around us.
They kept track of their positions by inventing
constellations, or shapes that can be traced
by connecting the dots.
They require quite a bit of imagination to
see, but our ancestors were creative and probably
quite bored, so they projected a little bit
of themselves onto the stars.
They also saw other objects, most notably
the sun and the moon, as well as five planets,
all of which moved according to their own
patterns, unrelated to the stars.
The planets were named for gods, and their
Roman names are the ones we still use today.
For a long time, we believed that the earth
was the center of the universe, with the mysterious
heavens swirling around us.
While this notion seems utterly ancient to
us now, it was the only conclusion we could
have made in absense of any scientific knowledge.
The planets moved along a particular line
through the sky, but a bit more slowly than
the stars, and the constellations they crossed
in doing so were viewed as special.
These were the constellations that came to
comprise the zodiac, which are still the focus
of astrology today, a relic of mysticism from
times past.
But some of what we learned in those times
remains valuable today.
We began to understand the cycles in the sky,
and we used them to understand time, the seasons,
and other phenomena.
The most obvious unit of time that mankind
has understood since prehistory is the day.
The sun rises and the sun sets.
This is the most noticeable cycle to any earth-dweller.
But other cycles were visible too.
The moon goes through phases in a predictable
way, and this became the basis for the month.
Over longer periods of time, we noticed seasons,
or regular periods of warmer and colder weather.
This became the basis for the year.
These are all units of time that mean nothing
whatsoever elsewhere in the universe, but
on the Earth, they mean everything.
They punctuate our human experience.
Now let’s discuss some more subtle observations
we made over many generations.
First, the stars rise and set just like the
sun and the moon, and they do so resembling
one huge sphere, with their distances from
one another fixed.
But after looking long enough, we realized
that there is one point that doesn’t move at all.
In the northern hemisphere this is called
the north celestial pole, and the southern
hemisphere has its south celestial pole.
These coincide with the north and south pole
of the earth, and the reason for this is fairly
intuitive in a modern context.
The star directly above the axis of rotation
for the earth will appear not to move, because
the north pole is a point that experiences
no lateral motion as the earth rotates.
This star, the north star, was useful for
navigation for thousands of years, and remains
useful to this day, leading any navigator
in a northward direction, no matter where
you’re standing in the northern hemisphere.
But for reasons that we now know have to do
with earth’s motion around the sun, the
celestial sphere changes very slowly throughout
the year.
Different stars are visible at different times
of the year, as well as different constellations,
and this was an important method of marking
the passage of time.
Rather than any meaningful message from the
gods, this phenomenon occurs simply because
we can’t see stars behind the sun, because
it’s way too bright, and at different times
in earth’s orbit around the sun, the sun
is blocking different stars.
We can only see stars during nighttime, when
the half of the earth we are on is pointed
away from the sun.
So some constellations go missing, and others
appear, until we get back to where we started,
all in a predictable, annual cycle.
The line that the sun traces in its movement
across the sky is called the ecliptic, named
as such because if the moon crosses this line
we have the potential to see an eclipse.
We now understand that this line, followed
by the planets as well, is simply the plane
of the solar system.
But the sun’s path changes depending on
the time of year, in a way that correlates
with the seasons.
So what are seasons, and why do we have them?
Many people think that this has to do with
the earth’s distance from the sun.
Farther away, colder, winter.
Closer, hotter, summer.
But summer in the northern hemisphere happens
at the same time as winter in the south, and
vice versa, so that can’t be right at all.
Instead, the seasons occur because of the
tilt in earth’s rotational axis.
This is the imaginary line that the earth
spins around.
As it turns out, this axis is not perpendicular
to the plane of the solar system, it’s actually
23.5 degrees from the vertical.
This means that one hemisphere is getting
more direct sunlight than the other at certain
times of the year.
In the summer, the axis of rotation is tilted
towards the sun, and the northern hemisphere
gets the most direct sunlight, while the southern
hemisphere gets sunlight at an oblique angle.
So the northern hemisphere gets more heat,
and more daytime.
In the winter, the axis of rotation is tilted
away from the sun, and the southern hemisphere
gets lots more sunlight.
More heat, and more daytime, while nights
get longer and colder up north.
This tilt also explains the varying angle
of the ecliptic.
Because of the way the earth is tilted during
different times in orbit, the sun will rise
and set at different places in the horizon.
The spring equinox, or vernal equinox, as
well as the fall, or autumnal equinox, are
the two days where the sun crosses the celestial equator.
The summer solstice and winter solstice are
the days where the sun is the furthest away
from the celestial equator, rising and setting
furthest north or south.
These days mark the passage of the four seasons,
and we were able to observe this in the sky
long before we knew why it happened.
Ancient monuments like Stonehendge, in England,
are very clearly structures based around these
phenomena, as in this case, the openings between
stone pillars are meant to frame the sunrise
and sunset for an observer standing at the
center, specifically on these special days.
Other monuments like pyramids and temples
exhibit some kind of alignment with the sun
on certain special days as well, but contrary
to whimsical conjecture, it is not necessary
to evoke aliens or magic to explain this.
It is just the result of careful observations
of the celestial sphere over many generations.
Lastly, the ancients were fascinated by the
moon, as it is the only object that significantly
changes its appearance over time.
The moon has cycles, in which it waxes and
wanes, from full to new to full again, with
crescent shapes in between.
These are called the lunar phases.
Their explanation is quite straightforward,
and contrary to popular belief, it has nothing
to do with shadows.
Only the face of the moon that is pointed
towards the sun is illuminated, and therefore visible.
If that side is pointed towards Earth, when
the moon is opposite the sun, the moon is full.
If pointed away, when the moon is on the same
side as the sun, it’s new.
Anywhere in between, and we get a crescent
of some kind.
If the moon passes directly between the sun
and the earth, that is called a solar eclipse,
and the moon will completely block out the
sun, leaving the earth in its shadow.
When the earth is directly between the sun
and the moon, leaving the moon in earth’s
shadow, that is called a lunar eclipse.
These were mysterious sights in the ancient
skies, often interpreted as ominous signals
from the gods.
But just as with everything else, we began
to learn how to predict these events as well.
Let’s continue and see what happened next
in our quest to understand  the cosmos.
