The Universe Might Just Be an Atom

Bright Side

Have you ever wondered if our universe could be as small as an atom? Some theories suggest that the universe might have started from a super tiny point, like an atom, and then expanded into what we see today. There's even a wild idea that a black hole might have given birth to our universe, acting like a cosmic seed. It's like thinking of our universe as just a tiny part of something much bigger. Mind-blowing, right?  Animation is created by Bright Side. ---------------------------------------------------------------------------------------- Music by Epidemic Sound https://www.epidemicsound.com   Check our Bright Side podcast on Spotify and leave a positive review! https://open.spotify.com/show/0hUkPxD34jRLrMrJux4VxV   Subscribe to Bright Side: https://goo.gl/rQTJZz  ---------------------------------------------------------------------------------------- Our Social Media: Facebook: https://www.facebook.com/brightside  Instagram: https://www.instagram.com/brightside.official TikTok: https://www.tiktok.com/@brightside.official?lang=en   Stock materials (photos, footages and other): https://www.depositphotos.com https://www.shutterstock.com https://www.eastnews.ru ----------------------------------------------------------------------------------------  For more videos and articles visit: http://www.brightside.me

Transcript

00:00Could it be that the entire universe is nothing more than just an atom?

00:05When you look at a diagram of an atom, which is a building block for all matter, you can

00:09see that some examples of the universe repeat.

00:13Our solar system is a great example of that.

00:16There's a giant central star and a couple of smaller planets that circle around it.

00:21You can observe the same arrangement outside our galaxy, too, with exoplanets orbiting

00:26their stars.

00:27And you can also witness that principle on a smaller scale.

00:30It's the way particles, called protons and neutrons, move around the center of an atom,

00:35which is called the nucleus.

00:37So imagine you have a bunch of positive magnets you're trying to stack together.

00:41They keep pushing each other away, right?

00:44That's what's supposed to be happening with the protons in an atom.

00:47They're all positively charged, so they should be repelling each other and flying off in

00:52all directions.

00:54Atoms do exist, so there must be something holding them together.

00:58And that something is called the strong interaction or strong force.

01:02The nucleus makes up less than one hundredth of a percent of the volume of the whole atom,

01:08but it usually takes up over 99.9% of the mass of the atom, once again similar to our

01:14Sun.

01:15Anyway, this strong interaction is like a special type of glue that holds the protons

01:19and neutrons together in the nucleus of an atom.

01:23In a similar way, gravity prevents us from flying away from the ground into the darkness

01:28of space.

01:29Now, this glue comes from some really smart particles inside protons and neutrons called

01:34quarks.

01:36These little guys have a strange kind of charge called color.

01:39It's not like the colors we see around us.

01:42It works like a code that helps quarks stick together inside their host particles.

01:47This code also seeps out and helps hold protons and neutrons together in the nucleus.

01:53In a way, quarks are like little builders that are working together to build atoms that

01:58make up everything around us.

02:00The Big Bang was said to be a magnificent moment when we got time and space.

02:05It's the story we use to explain the evolution of the Universe.

02:09In the beginning, there was only a very, very small ball of matter the size of a peach.

02:15With a temperature of more than a quadrillion degrees.

02:18Ow, that's hot!

02:20And this bang in the name doesn't mean there really was an explosion in space.

02:26This peach started spreading around, and space was just appearing everywhere.

02:30It gave rise to atoms, molecules, stars, and many celestial bodies that filled the empty

02:36space of our cosmos.

02:38Basically, all the elements that make us formed within a few minutes at the earliest stages

02:43of the Universe.

02:44Let's say, like a hundredth of a billionth of a trillionth of a trillionth of a second.

02:49Oh wait, give me a second to process that.

02:53Alright, moving on.

02:55The growth was incredible at that stage.

02:57The Universe spread exponentially and managed to double in size at least 90 times.

03:03Like me during the holidays.

03:04I love chocolate.

03:06After the Big Bang, the Universe was a hot and dense soup of particles, too hot for atoms

03:11to exist.

03:13But 380,000 years later, it cooled down enough for electrons to mix with nuclei and form

03:19atoms.

03:20This is a process we called recombination, and it's what made the Universe transparent.

03:25Think of it like turning on a light switch.

03:28Suddenly, you can see it all.

03:30But just because the Universe became transparent didn't mean it was bright.

03:34It was a dark period, as there were no stars or galaxies yet.

03:39Like a big empty canvas waiting for something to be painted on it.

03:43It wasn't until much later, as the Universe continued to evolve, that stars and other

03:48bright objects started to form and light up the darkness.

03:52And it went on evolving, all the while filling up with planets, asteroids, galaxies, and

03:57other things.

03:58Okay, so that's the story we've been told for the past couple of decades, and a pretty

04:03good one, I should admit.

04:05Scientists have studied it so much.

04:07They observed the leftover electromagnetic radiation from the young Universe.

04:12They measured the presence of the lightest elements, only to realize they all line up

04:16with the story of the Big Bang.

04:19New theories don't say the Big Bang didn't happen.

04:22It's a good picture of the cosmos in its early stages, but it's like an unfinished puzzle

04:27with some important parts missing.

04:29We can't explain what happened before the Big Bang using our current physics.

04:34So we need some new math to explain tricky parts.

04:37Like the so-called singularity.

04:39It's the point of infinite density, remember?

04:42From the beginning of the Big Bang.

04:45And that's where string theory comes in.

04:47Like a super-powered toolkit that can handle gravity and all other forces combined.

04:53One of the ideas that string theory has given us is the ekpyrotic Universe.

04:58Imagine a big fire that sparks off another fire, and that fire sparks off another fire,

05:03and so on.

05:04Well, in this scenario, the Big Bang wasn't the beginning of everything.

05:08It was just one part of a bigger process.

05:12It's the idea of the cyclic Universe, a never-ending rollercoaster ride, with big bangs as beginnings

05:18and big crunches as ends, happening over and over again, potentially forever.

05:24It's like the Universe is constantly hitting the reset button and does it in a really fun

05:29way.

05:30We could look at this singularity, according to some theories, as a single particle in

05:35a much larger system, much like an atom is made up of subatomic particles.

05:40And considering all that, the idea says every nucleus of an atom could have a Universe inside

05:46of it.

05:47So our entire Universe is just a tiny part of an atom in a much larger Universe made

05:53of atoms with more cosmoses with more atoms and more cosmoses.

05:58So twisting.

05:59The early versions of the idea of the cyclic Universe still had one big issue.

06:04They didn't match up with our observations of the cosmic microwave background, which

06:09is a fossil light that shows how the Universe looked when it was only 380,000 years old.

06:16So in March 2020, two physicists from Canada published a study that revealed the math behind

06:22the cyclic Universe that we missed earlier.

06:25If we focus on the moment when the Universe shrinks to an incredibly small point and then

06:30bounces back to a big bang state, we might be able to match up with our observations

06:35after all.

06:36It's just that we need to wait for more new experiments to fully test the idea.

06:42The Grand Unified Epoch.

06:44That's what we called a time when the Universe was still young.

06:47At that time, matter and antimatter, which are like mirror images of each other, existed

06:52in roughly equal amounts.

06:54But since they are opposing forces, when they come into contact with each other, they

06:58destroy each other in a powerful explosion, like fireworks.

07:02This means that even though matter and antimatter were constantly created and destroyed, somehow

07:09there was always a little more matter than antimatter, which is good because otherwise

07:14we wouldn't have anything left.

07:16As time went on, particles started to stick together and form more complex things, like

07:22atoms and molecules.

07:23And eventually, stars formed and created even heavier elements.

07:28But someday, a long, long time from now, all those stars will burn out.

07:33When the last star slowly cools and fades away, the Universe will turn into a dark void

07:39without life, light, or anything we know and assume there is.

07:43At some point, voracious black holes will eat all matter in space.

07:49Eventually even those black holes will evaporate away into the tiniest amount of light.

07:54Our cosmos will continue to expand.

07:56The light will become spread out and unable to interact with anything.

08:00So all activity in the Universe will stop.

08:04Space will become a vast, empty void, with no stars, planets, or anything else, and we'll

08:10end there.

08:11Or just begin.

08:13And maybe that's where we'll meet again.

08:15That's it for today!

08:16Hey, if you pacified your curiosity, then give the video a like and share it with your

08:21friends.

08:22Or if you want more, just click on these videos and stay on the Bright Side!

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