Perhaps youâve seen videos of how the planets
of the solar system move through the universe in this cool helix. But not only are these
misleading, Earthâs real motion - your real motion through the universe - is way more
complicated and way more interesting. This video of the planets moving in a corkscrew
pattern isnât exactly wrong, but itâs often presented in the most misleading sense
- by suggesting that the âoldâ idea of planets orbiting the Sun is wrong - and that
we really move in a cool vortex. This is misleading because it suggests that one frame of reference
- the one where we see the helix - is fundamentally better than any others. Today Iâm going
to say a word or two against this reference frame chauvinism, and then talk about how
the Earth REALLY moves through the universe, which involves a surprising amount of awesome
astrophysics.. To start, I want you to imagine youâre in
a ship moving steadily on a perfectly smooth ocean in an enclosed cabin. The portholes
are closed and thereâs no way you can tell how fast youâre moving. Or even that youâre
moving at all. This is the thought experiment that Galileo Galilei described in his 1632
book Dialogue Concerning the Two Chief World Systems to express what we now call Galilean
relativity. Itâs the idea that thereâs no single best frame of reference from which
to define the concept of stillness. Thereâs no absolute rest-frame. All non-accelerating
frames - also called inertial frames - can be taken as motionless as far as the laws
of physics are concerned. So the view of the Solar System tracing this
helix through space IS a valid frame of reference, but you know what else is a valid frame of
reference? This one. Where the planets orbit the Sun just like you were always taught.
At least on timescales of less than millions of years. OK, meme debunking achieved. Letâs
move on to the interesting astrophysics and talk about how Earth is really moving, and
what we can learn from that. Given this Galilean relativity of motion,
is it even meaningful to say how the Earth is moving? Well, there may be no such thing
as a single fundamental definition of motionlessness, but that doesnât mean all reference frames
are equal. We choose a reference frame thatâs most useful for the question at hand. For
example, if your brain is subconsciously computing the trajectory of a ball flying through the
air in order to catch it, youâre not going to take into account the fact that the surface
of the Earth is moving at 1000 km/hr or so due to its rotation. You can treat your patch
of the Earthâs surface as inertial for that calculation. If NASA wants to send a robot to Mars, it
probably doesnât want to use the frame of reference of Cape Canaveral, or even of the
Earthâs center to do its celestial mechanics. It uses an inertial frame of reference of
the solar system. But NASA gets to ignore the fact that the Sun is racing around the
galaxy at 230 km/s. So if we want to answer the question âhow
is the Earth really movingâ we need to choose the useful frames of reference. Letâs start
with the frame of reference of our familiar depictions of the motions of the planets - one
roughly fixed on the Sun. One thing is inaccurate about this depiction - and thatâs the idea
that the planets are orbiting the Sun, while the Sun is fixed relative to the planets.
The planets tug on the Sun just as it tugs on the planets, causing the Sun to move. The best reference frame to describe motion
within the solar system is that of the barycenter - the center of mass. This is the real point
that everything in the solar system is orbiting . From the reference frame of the barycenter,
the Sun executes this complex pirouette, mostly in response to the outweighed gravitational
pulls of Jupiter and Saturn. The Solar Systemâs barycenter is sometimes beneath the Sunâs
surface, but when the two giant planets are even vaguely lined up it can be quite a way
outside of the Sun. So how does this affect Earthâs orbit? The
barycenterâs motion is slower than Earthâs orbit. So this causes Earthâs elliptical
orbit to stretch and squish very slightly on the timescale of Jupiter and Saturnâs
years - 5 and 12 Earth years respectively. And the pull of the other planets also causes
the orientation of that ellipse to rotate around the Sun over 1000âs of years. We
talked about that effect in detail, and its connection to ice ages, when we discussed
the Milankovic cycles. So thatâs Earthâs motion within the solar
system - complicated, but not as complicated as its motion through the galaxy. That galactic
motion is also much harder to figure out. In the solar system, there are relatively
few bodies whose gravity you need to account for, and anyway, the gravity is massively
dominated by the Sun. The source of the Milky Wayâs gravitational field isnât dominated
by one object - everything orbits in the summed gravitational fields of everything
else. That makes things tricky, but it also means we can learn an enormous amount about
our Galaxyâs complex structure just by tracking the motion of its constituents. The Solar system is moving at about 230km/s
relative to the center of the Milky Way - give or take. That means a single orbit takes almost
230 million years. The last time the earth was on this side of the galaxy, dinosaurs
wandered Pangea and trilobites had just gone extinct. To describe the Sunâs motion through the
galaxy we need to choose a new reference frame. We could choose the center of the galaxy - but
thatâs actually very difficult to pinpoint. Instead we tend to describe the Sunâs complicated
motion relative to a much simpler hypothetical orbit - what we call the Local Standard of
Rest. The LSR is the reference frame that the Sun would have if it were executing a
perfectly circular orbit from its current position. This allows us to describe how ânot
circularâ the Sunâs orbit is. Thereâs also a good physical motivation. Almost every
star in the Milky Way disk starts in an orbit thatâs nearly circular. Thatâs because
the clouds of gas from which stars form get nudged into circular orbits due to friction
with other gas - friction that stars donât experience. After a star forms in the same
circular orbit as its birth cloud, it gradually gets nudged off that orbit by a miriad of
gravitational kicks from other objects in the Milky Way. Determining the speed of the sun with respect
to the LSR is just a matter of finding lots of new, young stars that formed recently and
are still in their birth orbits, and taking an average of how theyâre moving relative
to us. From these measurements we find that the sun is going a little bit faster than
it should be for a perfectly circular orbit- relative to the local standard of rest, the
Sun is drifting âforwardsâ at about 5 km/s. Itâs also drifting âinwardsâ toward
the galactic center at about 8 km/s and moving up and out of the disk at about 7 km/s. This
tiny âpeculiar motionâ as itâs called, has enormous consequences for the path that
the sun and solar system take through the galaxy. For starters, this slow drift toward the galactic
center doesnât mean weâre going to fall into Sagittarius A*. The Sun is trying to
execute a slightly elliptical orbit around the galaxy, and currently itâs moving closer
to the galactic center. But the Milky Wayâs mass is spread out through the entire galaxy
rather than concentrated in the center like in the solar system. That means simple elliptical
orbits arenât possible. Instead, the Sun traces out this pretty flower pattern over
many orbits. Geometrically itâs âepicyclicâ - the shape that a smaller wheel makes when
rolling on a bigger wheel. The slight upward motion of the Sun is perhaps
even cooler - and certainly quite a bit more impactful. I already mentioned that weâre
moving up out of the galactic disk at around 7 km/s. We are currently a few dozen lightyears
above the middle, although itâs hard to know exactly where the center of the galactic
disk is. Weâre not in danger of escaping the galaxy. With more matter below than above
us, the diskâs gravity is slowing our upwards motion. In a few million years weâll have
clawed our way to around 300 light years above the disk center before our upwards motion
slows to a halt, and we begin to fall back in. Weâll plummet through the disk, overshoot,
and pop out the other side. We execute one of these graceful leaps roughly once every
60Â million years, so a few times per galactic orbit. This vertical oscillation is more than just
a curiosity. Some astronomers think it could be directly tied to mass extinctions on the
earth. You know the dinosaurs went extinct 60 million years ago. The center of the disk is a more dangerous
place for the solar system due to the higher density of stars. It puts us at a bigger risk
of a nearby supernova, or close encounters with other massive objects that could destabilize
debris in the outer solar system that could impact the earth. But thatâs a story for
another time. This bouncing motion of the sun and other
stars is also a useful scientific tool - it gives us a way to test different theories
of the mysterious dark matter which is invisible and has only been detected by its strong gravitational
influence. There are many different models for what type of particle or object dark matter
is made up of, and these models make different predictions for how dark matter interacts
with itself. In the more mainstream models it interacts with itself almost not at all,
which means it stays very puffy and spread out. But some dark matter candidates might
experience very weak self-interactions, resulting in a force similar to friction and enabling
dark matter to accumulate in the disk of the galaxy, that would lead to a more massive
disk than the case where dark matter is more spread out. So by weighing the disk we can
potentially test these types of dark matter models. And we can do that by looking at the
vertical oscillations of stars. Thatâs because the mass of the disk determines how far stars
can rise in these vertical oscillations. Measuring vertical speeds and maximum heights for nearby
stars has so far told us that thereâs no evidence of any extra density of dark matter
in the disk, which supports non-interacting dark matter models. Okay, now we know how the sun moves through
the galaxy, but what about the solar system as a whole? The plane of the planetâs orbits
- also called the ecliptic plane - is tilted by about 60 degrees. That's why we see this
sort of squished corkscrew pattern as the planets move through the galaxy. The orbits of the planets cause them to spend
half their year ahead of the sun in the galactic orbit, while they lag behind it during the
other half. In the case of the earth, itâs the furthest ahead of the sun in September,
while in March itâs farthest behind. Also, for half the year Earth is moving in the same
direction as the Sun through the galaxy so their velocities add together, with the maximum
speed in June. While in the other half of the year weâre moving backwards relative
to the Sunâs motion, so in December Earthâs galactic motion is the slowest. This change in Earthâs galactic speed also
happens to be useful for testing - guess what - dark matter models. If dark matter is some
exotic particle, then it must be passing through the Earth as we move through the galaxy. And
the faster we move, the more dark matter we should sweep through, in the same way that
more rain hits your windshield the faster you drive. Dark matter experiments should
see more events in June compared to December. In fact, physicists at the DAMA experiment
in Gran Sasso in Italy actually may have detected this signal though thatâs still disputed-
partly because other detectors havenât been able to reproduce it yet. Okay, just one more bone to pick about this
so-called vortex motion. Currently the ecliptic is almost face-on compared to our Sunâs
orbital motion, so the corkscrew is valid. But due to conservation of angular momentum,
the plane of the solar system wonât âturnâ with the Sunâs orbit. After a quarter of
a galactic orbit, the ecliptic plane will be edge-on - the solar system will be like
a great wheel rolling in the direction of the sunâs orbit. We now have a picture of how the Solar system
really moves through the galaxy. But how do we move through the universe as a whole? The
Milky Way is pulled by the gravitational fields of the masses around it. Weâre racing towards
the Andromeda galaxy at a couple of hundred kilometers per second, while our entire local
group - Andromeda, the Milky Way, and the other little galaxies around us - are being
pulled at several hundred km/s towards a mysterious overdensity in the clustering of galaxies
called the Great Attractor. At this point, it becomes really tricky to define a single
frame of reference to precisely define our relative velocity. Except we do have one last recourse - a reference
frame granted to us by the earliest epochs of the universe. The reference frame of the
cosmic microwave background. This is the faint, radio-wavelength light that was emitted by
the hot hydrogen that filled the universe before the first stars were born. Those hydrogen
atoms were moving in all different directions, but they had an average velocity. If you were
there near the beginning, and you were moving at the average velocity of those atoms, then
the light produced by those atoms would look the same in all directions. However if you
had any different velocity, then the light hitting you from ahead would be a bit more
energetic - a bit bluer. Light hitting you from behind it would be less energetic, or
more red. Well, those atoms are mostly in stars now,
but the light they produced is still everywhere. The cosmic microwave background defines a
rest frame for the universe. And we can check our reference frame compared to it. It turns
out that we are hurtling at 368Â (+ or - 2)Â km/s relative to the cosmic rest frame - weâve
been tugged from the cosmic average velocity by vast overdensities of galaxies hundreds
of millions of light years away. So that is how you are currently moving through
the universe. Itâs wildly dizzying in all but the reference frame of your own body.
At the most extreme, you are wheeling in squished corkscrew that shifts to a rolling wheel as it dips
above and below the galactic disk tracing flower petals around the Milky Way, which
in turn forms a galaxy-scale helix, the sum total of our wheeling dance across space time. In our last episode we explored the possibility that life could be based on silicon rather than carbon. I concluded that
carbon is way better than silicon for life, but there was some deep discussion on the topic in the comments. Appletank8 suggests exploring whether thereâs
a form of photosynthesis or chemosynthesis that can break up SiO2, noting that if even
the bottom of the food chain doesnât work, then nothing else will either. This is an excellent insight, and is one of the key reasons why silicon-based life may well be impossible.
In fact there is no known enzyme capable of breaking the silicon dioxide molecule. That
means the end of the silicon-based chemical pathway may really be a dead end. Silica may
simply be too stable, and so silicon is too easily locked out of circulation for any evolutionarily-plausible
biochemistry. Compare that to carbon dioxide, which is relatively easily broken to get the
carbon back into circulation. Perhaps there are novel ways to release the silicon from
silicon dioxide that we havenât thought of yet - but thereâs no question that the
carbon base is a much easier path to life, and so it will out-compete silicon in most
circumstances. FatherDragonKal asks why not Boron or Nitrogen
based life as well? The main reason is simply that boron and nitrogen donât form long
molecular chains with themselves, so they canât form scaffolding structures for a
wide variety of molecules. Sulfur can form long 1-D chains with itself, but canât append
multiple molecules due to it only having two covalent bonds. Carbon and silicon can form
1-D and 2-D structures and append multiple other atoms, but of these only carbon has
the various properties that make it ideal for life - all the stuff we talked about in
that episode. ǡynnĹĽari asks whether weâve considered
life that isnât similar to Earth life. The answer is yes, but thereâs a reason we tend
to focus on at least chemical life. Science fiction is full of ideas, from sentient oceans in Solaris to nuclear life on neutron stars in Robert Forwardâs Dragonâs Egg. But scientists have also tried to come up with a non-chemical basis for life. Like
self-sustaining data structures in crystals, or magnetic monopoles on cosmic strings inside
stars - we covered that once, or dust particles suspended in plasma. But everything Iâve
ever heard of king of feels like a stretch - all of it seems way harder than good olâ chemical, and preferably carbon based life. You know what, let me tell you what I really think about this - The apparent fine tuning of this universe strongly suggests to me that thereâs a multiverse
of some type of other, and the vast majority of universes are uninhabitable. We naturally
observe a universe that happens to have the qualities to make at least one form of life
possible. But the chance for a given universe to be tuned so finely that multiple forms
of life are possible is very close to zero. So yeah, other forms of life exist out there
- but âout thereâ probably means several universes away. Many, many people noticed that the molecule
we showed for nitroglycerine was actually TNT. And, as Benedictul points out, these
are definitely not the same thing despite the misinformation spread by AC/DC - accadacca
to their fiends and compatriots. Itâs incredibly impressive that there are so many of you that can immediately distinguish these molecules at a glance. As you can tell, Iâm not in
that elite group. I do apologize and will try to memorize more chemical structures for the future.
Such an awesome episode. It's one thing to think about your place in the universe, but it's something else entirely to think about our motion through it.
Imagine: You're moving >823k miles an hour relative to the cosmic microwave background.