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  • We're living in this time where most of the matter is dark. We're not actually seeing

  • it. And most of what we call the energy density of the universe appears to be dark as well.

  • So, we're in what I like to call this period of maximum ignorance right now, where we've

  • learned a ton about all of the normal matter of the universe everything that makes you

  • and the Earth and the Sun. But, what we know today is that's only less than 5% of the universe.

  • And then, the other 95%, we don't know. The majority of that 95% is dark energy, a mysterious

  • force that's expanding the universe faster and fasterCosmologists from around the

  • world are unsure why this acceleration is happening. That's why in the absence of

  • data, an international team of scientists and engineers are building a dark energy hunting

  • machine to probe the far reaches of the universe to a point in spacetime few have ever seen.

  • So we call it dark energy because we don't know what it is. We can detect it through other

  • measurements, but we can't observe it directly. Scientists first became aware of dark energy

  • in the late 1990's after two independent teams of astrophysicists were racing to determine

  • the rate at which the universe was expandingBoth teams expected to see the expansion slowing

  • down, due to the long established theory that the attractive force of gravity was pulling

  • the universe together. However, they observed something completely unexpectedThe expansion

  • of the cosmos was speeding up, not slowing down, meaning that there must be something

  • like the appearance of an anti-gravitational force at play. We looked at that as like,

  • Oh, yeah. That's weird. That can't possibly be right. They must have done something wrong.

  • So, it seemed pretty easy to dismiss it at the time. But with further experiments and

  • observations, the initial findings continued to hold upIn fact, those original papers

  • from 1998 and 1999, they knew what they were doing. They got it exactly rightThis repulsive

  • force which we now call 'dark energy', is something that still perplexes us.

  • It's easier to say what we do know about dark energy than what we don't know. So, what we do know

  • is that in the early universe, it was not very important. But, at some point between

  • six or seven and eight billion years after the Big Bang until today dark energy became

  • the dominant force affecting what's happening to the universe as a whole. We know it's not

  • a particle because if it were caused by some particle, there would be other manifestations

  • of it. So, it appears to be something like a force. And at the moment, it's a very data-starved

  • discussionEvery week it seems, there are new theories coming out. Some of them having

  • to do with this modification of our laws of gravitySome having to do with introducing

  • new forces in the universe that would be a dark energy force or forcesAnd then, there

  • are other even grander ideas about additional dimensions in the universe effectively leaking

  • in on the four dimensional space that we see and exerting this force on our space.

  • One of the first next big experiments to really measure this at this precision level is the

  • DESI experiment. DESI is a fiber optic spectrograph that will construct a 3D map of the universe,

  • tracing close to 12 billion years of cosmic history. This engineering marvel is being

  • mounted onto a telescope in Arizona where it will measure the spectra of more than 35

  • million galaxies to observe dark energy's effect on a much grander scale.

  • We're using new classes of optical designs to get these large fields of view. A big part of

  • the DESI project was making this beast that we call the optical corrector that's really

  • glasses on the top of the telescope. It's a set of six lenses where the largest lens

  • is 1.1 meters in diameter. And all of these lenses are polished to a precision.

  • Okay so check, we've done that, big field of viewThe next challenge was figuring out how to catch

  • the light of multiple galaxies at the same timeWe have a lot more fibers. We have

  • 5,000 fibers and we also have a really quickly reconfigurable focal plane. Each robot can

  • move individually, so we can reposition every single fiber at the same timeSo we cut

  • down the time between observations from a few hours down to three minutes. Which means

  • with each fiber aimed at the sky. We can map 5,000 galaxies every 15 minutes.

  • The main goal of the fiber system is to preserve the quality of light that the telescope delivers.

  • You know, these photons have spent billions of years reaching us.

  • We do everything possible within that fiber system to deliver the light to the spectrograph without

  • degrading it. The spectrograph is 10 identical units that fill an entire room.

  • DESI is nearing completion of its installation phase and gearing up to scan the skies. We have the focal plane

  • installed, and then after the focal plane is safe to operate, then we install the fiber

  • cables to the slits. We'll make a precision map of the geometry of the universe from the

  • distance of about seven billion light years to about 10 or 11 billion light years.

  • And so this is the phase of history of the universe where dark energy turned on. Where it became

  • the dominant force in the universe. So, to construct a 3D map and understand dark energy's

  • role, DESI will first need to look at a unique cosmological effect. The universe did deliver

  • a specific feature that we can latch onto and that's this baryon acoustic oscillation

  • feature. When the universe went through this specific transition where it was a plasma

  • of very hot ions and then cooled off it was 383,000 years after the big bang, right at

  • that time there were sound waves propagating in the universe that got frozen in.

  • Mapping those soundwaves with DESI will give scientists a sense of the distribution of the galaxies

  • and scale of the universeBut BAO's don't give us the whole pictureIn this age of

  • accelerated expansion, galaxies are moving away from us, so scientists need to measure

  • how fast they're travelingFortunately, galaxies leave a clue behind: their light waves.

  • These waves are stretched to redder and redder wavelengths, which is called their redshift.

  • By knowing a galaxy's redshift, scientists can tell how far away it is and

  • turn our view of the sky into a 3D mapIn the first year of operations starting in

  • 2020 we'll actually have a larger map of the universe than all of humanity before us.

  • So we'll be able to verify what our understanding of dark energy is today, geometry at a few

  • different epochs, how dark matter is pushing around these galaxies. That's what we'll see

  • after the first yearThen it'll be the subsequent years where we'll have a large enough map

  • that it'll really be the new discovery potential for dark energy.

  • These cosmic map makers are charting the open sky, uncertain of what they'll eventually find.

  • But diving into the unknown is just part of the job. What they learn in the end will only expand our

  • knowledge of the universe, and our small place in it. The better we understand dark energy,

  • the better we understand how the universe is going to evolve and we learn what's going

  • to happen to the universe in the end. What I can tell you is that these will be the best

  • data that we have once we complete this map, and it will certainly rule out many, many

  • potential models for dark energy.

  • It'll be very interesting to see what's left on the table after that.

We're living in this time where most of the matter is dark. We're not actually seeing

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