The universe is bustling with matter and energy.
Even in the vast apparent emptiness of intergalactic space,
there's one hydrogen atom per cubic meter.
That's not the mention a barrage of particles
passing every which way from stars, galaxies, and into black holes.
There's even radiation left over from the Big Bang.
So is there such thing as a total absence of everything?
This isn't just a thought experiment.
Empty spaces, or vacuums, are incredibly useful.
Inside our homes, most vacuum cleaners work
by using a fan to create a low-pressure relatively empty area
that sucks matter in to fill the void.
There's still plenty of matter bouncing around.
Manufacturers rely on more thorough, sealed vacuums
That includes vacuum-packed food that stays fresh longer,
and the vacuums inside early light bulbs that protected filaments from degrading.
These vacuums are generally created with some version
using high-powered pumps that create enough suction
to remove as many stray atoms as possible.
But the best of these industrial processes
tends to leave hundreds of millions of atoms
per cubic centimeter of space.
That isn't empty enough for scientists who work on experiments,
like the Large Hadron Collider,
where particle beams need to circulate at close to the speed of light
for up to ten hours without hitting any stray atoms.
So how do they create a vacuum?
The LHC's pipes are made of materials, like stainless steel,
that don't release any of their own molecules
and are lined with a special coating to absorb stray gases.
Raising the temperature to 200 degrees Celsius
and hundreds of vacuum pumps take two weeks to trap enough gas and debris
out of the pipes for the collider's incredibly sensitive experiments.
the Large Hadron Collider isn't a perfect vacuum.
In the emptiest places, there are still
about 100,000 particles per cubic centimeter.
But let's say an experiment like that could somehow get every last atom out.
There's still an unfathomably huge amount of radiation all around us
that can pass right through the walls.
Every second, about 50 muons from cosmic rays,
10 million neutrinos coming directly from the Big Bang,
30 million photons from the cosmic microwave background,
and 300 trillion neutrinos from the Sun pass through your body.
It is possible to shield vacuum chambers with substances,
that absorb and reflect this radiation,
Let's say you've somehow removed all of the atoms
and blocked all of the radiation.
Is the space now totally empty?
All space is filled with what physicists call quantum fields.
What we think of as subatomic particles,
electrons and photons and their relatives,
are actually vibrations in a quantum fabric
that extends throughout the universe.
And because of a physical law called the Heisenberg Principle,
these fields never stop oscillating,
even without any particles to set off the ripples.
They always have some minimum fluctuation called a vacuum fluctuation.
This means they have energy, a huge amount of it.
Because Einstein's equations tell us that mass and energy are equivalent,
the quantum fluctuations in every cubic meter of space
have an energy that corresponds to a mass of about four protons.
In other words, the seemingly empty space inside your vacuum
would actually weigh a small amount.
Quantum fluctuations have existed since the earliest moments of the universe.
In the moments after the Big Bang,
they were amplified and stretched out to cosmic scales.
Cosmologists believe that these original quantum fluctuations
were the seeds of everything we see today:
galaxies and the entire large scale structure of the universe,
as well as planets and solar systems.
They're also the center of one of the greatest scientific mysteries of our time
because according to the current theories,
the quantum fluctuations in the vacuum of space
ought to have 120 orders of magnitude more energy than we observe.
Solving the mystery of that missing energy
may entirely rewrite our understanding of physics and the universe.