How Did the First Atom Form? Where did it come from? | Big Bang Nucleosynthesis
Summary
TLDRThis video script delves into the origins of atoms and the universe, explaining the Big Bang as a period of rapid expansion, not a singular starting point. It outlines the timeline of the universe's early moments, from the Planck epoch to inflation, and discusses the formation of fundamental particles, the quark epoch, and the emergence of stable atoms. The script also touches on the mystery of matter-antimatter asymmetry and the cosmic microwave background, setting the stage for the exploration of heavier elements' creation in a subsequent video.
Takeaways
- 🌌 The universe is composed of an immense number of atoms, estimated to be more than 10^78.
- 🔬 Atoms are made up of subatomic particles: electrons, protons, and neutrons, which are themselves composed of quarks.
- 💥 The origin of the particles that make up atoms is believed to be the Big Bang, where immense energy condensed to form atoms.
- ⏳ The Big Bang theory is not about the exact moment the universe began but rather the period of rapid expansion and high density that followed.
- 🚫 Our understanding of the universe's beginning is limited by incomplete theories that break down near the 'singularity' at t=0.
- 🕒 The Planck epoch, around 10^-43 seconds after the Big Bang, is the earliest period we can theoretically understand, requiring a quantum theory of gravity.
- 🔄 The universe underwent a phase of inflation, expanding exponentially faster than the speed of light, which is not a violation of causality.
- 🌀 The forces of nature, including gravity, are thought to have unified into a single force during the Planck epoch and then separated as the universe expanded.
- 🌡 The universe transitioned from a quark-gluon plasma to a hadron gas as it cooled, leading to the formation of protons, neutrons, and electrons.
- 💥 A matter-antimatter asymmetry resulted in a slight excess of particles over antiparticles, allowing for the formation of stable atoms.
- 🌟 The cosmic microwave background (CMB) is the residual radiation from the time when the universe became transparent as electrons combined with nucleons to form neutral atoms.
Q & A
What is the estimated number of atoms in the observable universe?
-There are estimated to be more than ten quadrillion vigintillion atoms in the observable universe, which is 1 followed by 78 zeros.
What are the basic components of an atom?
-Atoms are made up of electrons, protons, and neutrons, which in turn are composed of quarks.
What is the short answer to where the particles that make up atoms came from?
-The short answer is the Big Bang, where immense energy condensed and atoms formed.
What is the limitation of our current understanding of the universe's beginning?
-Our current theories are incomplete, and we cannot accurately describe what happened at the very beginning of time, known as the singularity.
What is the Planck time and why is it significant?
-The Planck time is about 10^-43 seconds, the smallest unit of time that can theoretically exist according to quantum mechanics. It is significant because it is the closest point in time to the beginning that we can theoretically understand.
What is the concept of inflation in the context of the Big Bang?
-Inflation is a theorized period from about 10^-36 to 10^-33 seconds after the Big Bang when the universe expanded exponentially faster than the speed of light.
Why is the Big Bang not considered as an event at t=0?
-The Big Bang is not considered as an event at t=0 because it refers to a period in the early universe when it was very hot, dense, and expanding rapidly, rather than a specific starting point.
What is the significance of the electroweak symmetry breaking?
-Electroweak symmetry breaking, occurring around 10^-11 seconds, is significant because it led to the separation of the electromagnetic and weak forces and allowed fundamental particles to gain mass through interaction with the Higgs field.
What is the matter-antimatter asymmetry and why is it important?
-The matter-antimatter asymmetry refers to the imbalance between the creation of particles and antiparticles. It is important because it allowed for the existence of matter in the universe, as without it, all particles would have annihilated with antiparticles, leaving only photons and neutrinos.
What is the cosmic microwave background (CMB) and how is it related to the formation of the first atoms?
-The cosmic microwave background (CMB) is the residual radiation from the Big Bang. It is related to the formation of the first atoms because it was released when the first stable neutral atoms were formed, allowing photons to travel freely through space.
What is the process of Big Bang nucleosynthesis and what elements were formed during this process?
-Big Bang nucleosynthesis is the process that occurred around 17 minutes to 20 minutes after the Big Bang, during which the universe formed its first elements, primarily Hydrogen and Helium-4, along with trace amounts of deuterium, Helium-3, and Lithium-7.
Outlines
🌌 The Big Bang and the Birth of Atoms
This paragraph delves into the fundamental concepts of the universe's composition and the origins of atoms. It introduces the concept of the big bang as the starting point for the formation of atoms and explains the limitations of our current understanding of the universe's inception. The paragraph also touches upon the Planck epoch, the earliest point in time we can theoretically access, and the challenges of understanding what occurred before this. It sets the stage for the journey through the early universe's timeline, leading up to the formation of atoms.
🚀 Cosmic Inflation and the Quest for Understanding the Universe's Early Moments
The second paragraph explores the concept of cosmic inflation, a period of rapid expansion in the early universe that occurred between 10^-36 and 10^-33 seconds post-big bang. It discusses the mysteries surrounding the energy source that fueled this expansion and the information loss it caused. The paragraph also touches on the standard model of cosmology, which is well understood from around 10^-12 seconds, and the speculative nature of theories before this time. It outlines the timeline of the universe's evolution, including the separation of forces and the formation of a quark-gluon plasma, setting the stage for the emergence of mass through the Higgs field.
🔬 The Formation of Atoms and the Matter-Antimatter Asymmetry
This paragraph examines the process of atomic formation in the early universe, starting from the quark epoch and moving through the lepton epoch. It explains how the universe transitioned from a state of quarks and gluons to a hadron gas, which included protons, neutrons, and mesons. The discussion includes the annihilation of particles and antiparticles, leading to a slight excess of particles that allowed for the formation of atoms. The paragraph also highlights the mystery of matter-antimatter asymmetry and the significance of this imbalance in the creation of the first atoms.
🌟 The Cosmic Microwave Background and the Formation of Neutral Atoms
The final paragraph of the script discusses the process of recombination, where electrons finally become bound to nucleons to form neutral atoms, which occurred around 380,000 years after the big bang. It explains how this event led to the universe becoming transparent, allowing photons to travel freely and create the cosmic microwave background (CMB) that we observe today. The paragraph also hints at the continuation of the story in a subsequent video, focusing on the formation of heavier elements essential for life and introduces a sponsored course on chemical reactions available on Brilliant.
Mindmap
Keywords
💡Atoms
💡Big Bang
💡Planck Time
💡Inflation
💡Electroweak Force
💡Higgs Field
💡Quark-Gluon Plasma
💡Nucleosynthesis
💡Recombination
💡Cosmic Microwave Background (CMB)
💡Matter-Antimatter Asymmetry
Highlights
The universe is composed of atoms, which in turn are made of electrons, protons, and neutrons, and these are composed of quarks.
The number of atoms in the observable universe is estimated to be more than ten quadrillion vigintillion.
The origin of the particles that make up atoms is believed to be the Big Bang.
The Big Bang is not a theory explaining the beginning of the universe, but rather a model of the early universe.
Our current theories are incomplete, and the standard model of cosmology becomes unreliable close to the beginning of time.
The Planck time, about 10^-43 seconds, is the smallest unit of time that can theoretically exist according to quantum mechanics.
The Planck epoch is the first epoch of the universe, where gravity and other forces are expected to have been unified.
Inflation occurred from about 10^-36 to 10^-33 seconds after the Big Bang, during which the universe expanded faster than the speed of light.
Cosmic inflation is a process that destroys any information about what came before it.
The standard model of cosmology is well understood starting at about 10^-12 seconds after the Big Bang.
The universe consisted of quarks and gluons in a quark-gluon plasma, along with other fundamental particles, before the electroweak symmetry breaking.
The Higgs field gained a non-zero potential at about 10^-11 seconds, leading to the particles of the Standard Model obtaining their rest mass.
The universe was too hot for quarks to combine into hadrons like protons and neutrons until about 10^-5 seconds after the Big Bang.
The matter-antimatter asymmetry is one of the biggest unsolved puzzles in physics, with more particles than antiparticles being created.
The Big Bang nucleosynthesis occurred around 20 minutes after the Big Bang, resulting in a universe composed mainly of hydrogen and helium-4.
Recombination happened around 380,000 years after the Big Bang, when electrons finally bound to nucleons to form stable neutral atoms.
The cosmic microwave background (CMB) is the light released as the first stable neutral atoms were formed, providing a record of the early universe.
The formation of the first atoms in the universe is only the beginning of the story, with the heavier elements essential for life formed later.
Brilliant offers a course called 'The Chemical Reaction' that explores the fundamentals of chemistry from the perspective of chemical reactions.
Transcripts
This video is sponsored by Brilliant. Stay tuned to the end for a very special offer
for Arvin Ash viewers. You and the world around you are made up of
millions and millions of atoms, heck there are estimated to be more than ten quadrillion
vigintillion atoms in the observable universe. That is 1 followed by 78 zeroes.
But what are atoms? Atoms are tiny particles made from electrons, protons and neutrons,
which are in turn composed from quarks. But that raises the question, where did the particles
that make up these atoms come from in the first place?
The short answer is the big bang. In the early universe there was an immense amount of energy,
yada, yada, yada - The energy condensed, atoms formed.
But as you might suspect, there’s a lot that happened in the yada, yada, yada step.
So what really happened? What is the big bang really in a scientific sense? The answer,
which might surprise you, is coming up right now…
To understand what the big bang really is in a scientific way, we must take a closer
look at what happened in the early universe. But to do that, we need to have some kind
of a timeline. This means we need some place where this timeline starts.
The truth of the matter is that while the big bang is often thought of as the theory
explaining the beginning, it’s actually not. We don’t know anything concrete about
when the universe actually started, or whether it even did.
The most we can do is use our best model of the universe, called the standard model of
cosmology, and use this to turn the clock back to get as close to the beginning of time
as we can. But if when can do that, why can’t we just turn the clock back to the very beginning,
at t = 0? In short, the problem is our
theories are incomplete and at some point, very close to the beginning of time, the theory
becomes unreliable. The theory predicts a singularity, a moment in time when all the
matter and energy in the universe, in other words all of creation was in an infinitesimally
small point of infinite density. Most physicists believe this is probably wrong.
The best we can is go back up to one Planck time, about 10^-43 seconds. This is the smallest
unit of time that can theoretically exist according to quantum mechanics. We have no
idea what comes before this. So although this is close to the beginning, it not quite t=0.
Even to understand what happens here at 10^-43 seconds, we would need a quantum theory of
gravity, because it is here where gravity, the theory of the very large, meets quantum
mechanics the theory of the very small because all matter and energy, and thus gravity would
be confined presumably to the tiny scales of quantum mechanics.
This 10^-43 seconds is considered the first epoch of the universe and is often called
the Planck epoch or era. Around this Planck epoch we expect that there
was a point at which all the forces; electromagnetism, the weak and the strong force united with
gravity forming one grand unified force. So, to build a timeline for our big bang theory
we start before the Planck epoch and set the clock to zero at this point. Keep in mind
that this is not really t=0, but we start here anyway because it’s the best we can
do without running into the singularity. There might have been something before, but we don’t
know, and we also don’t really know how the universe looked during this epoch or what
happened. The earliest time we can theorize what happened
is around the time of inflation. This happened from about 10^-36 seconds to about 10^-33
seconds after the big bang. This is when whatever existed prior to this
time, let’s call it the singularity for convenience, grew exponentially fast, faster
than the speed of light. This is permissible because there is no theoretical restriction
on how fast space can expand. It grew from a point to about the size of a large orange.
Now you might say, but I thought you can’t break the speed of light! But actually, you
can. What Einstein’s found is that information can’t be transferred faster than the speed
of light. This ensures that you always have a cause and then effect. Causality is preserved.
But because cosmic inflation occurred faster than the speed of light, it means that two
points in space that could affect each other before inflation, in other words, two points
that were causally connected, might not be causally connected after inflation, since
they moved apart faster than light. The things we currently understand occur mostly
after inflation. Thus, the proper way to understand the term
“big bang”, is not as some point or object from which the universe started or came into
existence, but as a period in the early universe, when the universe was very hot, very dense,
and expanding rapidly. So the big bang is NOT what happened at t=0,
it’s everything that happened after that. Inflation is thought to have occurred from
10-36 to about 10-33 seconds . Where did the energy come from to cause this rapid expansion?
This problem has not been solved. Cosmic inflation is a process that destroys any information
about what came before it. The theory of the standard model of cosmology
is really only well understood starting at about 10-12 seconds, because the universe
at this point had energies that can be approximately replicated in current particle accelerators.
Prior to this timeframe, we can only speculate. So, anything that we talk about prior to this
is largely speculation. We can turn the clock scientifically almost all the way back, but
not quite. We don’t know much about what happened during
the period after inflation from about 10-33 seconds to 10-12 seconds.
In terms of the forces, gravity is thought to have separated from the unified force shortly
after the Planck Epoch at 10^-43 seconds. And later, the strong force is thought to
have separated at around the time of inflation 10^-32 seconds. But from 10^-32 seconds to
10^-12 seconds, the electromagnetic and weak forces were still united as the electroweak
force. And at this point, the laws of the standard
model of particles physics tells us the universe probably consisted of quarks and gluons existing
together in a quark-gluon plasma, along with some other fundamental particles.
But importantly at this point all these fundamental particles were massless, because the Higgs
field was massless at this point – in other words, it has not gained a non-zero potential
that allows fundamental particles to gain mass by interacting with it.
Where these initial massless fundamental particles came from is still not known. It's possible
they somehow condensed from the energies present at the big bang, or there might have been
an initial scalar field, similar to the Higgs field, called the inflation field, which consisted
of Inflatons that decayed to the fundamental particles we see today.
As time ticks slightly forward to about 10^-11 seconds, and the temperature of this hot universe
falls a bit further to about 10^15 or one quadrillion Kelvin. The lower temperatures
and energies leads to something called electroweak symmetry breaking and the beginning of the
quark epoch. What happens this stage is that the electromagnetic and weak forces become
distinct and separate forces. This leads to the Higgs field gaining a non-zero
potential – which looks like a Mexican hat called a Sombrero. This means that the fundamental
particles that now interact with the Higgs field, gain mass. This is how the particles
of the Standard Model obtained their rest mass.
If you want to learn more about the electroweak symmetry breaking and how Higgs potential
causes the particles to become massive, check out my video about electroweak theory.
At this point we have all the building blocks for atoms. Again the time is around 10-11
seconds after the beginning, and the temperature of the universe is around 1 quadrillion Kelvin.
The universe is however still too hot for the quarks to combine together to form hadrons
like protons and neutrons. This changes as the universe keeps expanding
and further cooling takes place. As temperatures cool to around 1 trillion Kelvin at 10-5 seconds,
the quark plasma turns into a hadron gas consisting of protons, neutrons, and some mesons. The
Mesons are a combination quark, anti quark pairs that eventually decay into photons and
electrons. As the universe keeps cooling down, the antiparticles
now begin annihilating with particles creating lighter particle and antiparticle pairs, eventually
ending up as the lightest particles - neutrinos and photons.
While we would expect that an equal amount of particle and anti-particles would be created,
this didn’t happen. For some reason more particles were created than antiparticles,
about one in 10 billion more. The reason for this matter-antimatter asymmetry is one of
the biggest unsolved puzzles in physics. If this annihilation were symmetric, meaning
the same amount of particles and antiparticles were converted, then we would have had a universe
consisting of nothing except photons and neutrinos, that is, no quarks or electrons, and thus
no atoms. Luckily there were ever so slightly more particles
than anti-particles, so that some quarks and electrons survived the annihilation, and protons,
neutrons and electrons that would eventually turn into the first atoms, were able to be
formed. This annihilation of particles ends with the
lepton epoch at around the 1 second mark. The temperatures at this stage cooled down
to around 5 billion Kelvin. Leptons are the lightest matter particles and therefore the
last particles to finish this annihilation process.
After this fire show, most of the matter particles in the universe had been destroyed and turned
into photons and neutrinos. But as I said, because of the mysterious matter-antimatter
asymmetry, a few protons, neutrons, and electrons were left over, the building blocks needed
for atoms. Protons on their own are technically hydrogen
nuclei. You can think of them as positively charged or ionized hydrogen atoms. But we
are interested in where the stable neutral atoms come from. To do this, more time had
to pass, and physics had do its thing. When the universe was a few minutes old, the
temperature dropped below 1 billion Kelvin and it reached the point of the big bang nucleosynthesis,
also called the BBN. Initially protons and neutrons were produced
in equal numbers, but free neutrons are actually not stable, unlike protons. This is related
to the fact that neutrons are slightly heavier than protons, making them less stable than
protons. If left free, a neutron will undergo something called beta decay, via the weak
force, into a proton in about 10 to 15 minutes. After the protons and neutrons were formed,
the temperature was so hot, that the conversion from proton to neutrons, was equal to the
conversion from neutron to protons. But as the universe cooled down, this process changed
and the decay of neutrons began to dominate. As it turns out, neutrons can become stable
when they are in a bound state with other neutrons and/or protons, but not on their
own. So, at this point in the story, it was a race
against time for these free neutrons to bind with other hadrons and form larger nuclei before
they decayed. The big bang nucleosynthesis lasts for around
17 minutes until the universe is around 20 minutes old. During this process, a lot of
neutrons manage to form bound states and thus survive, but many decayed into protons. And
this why we have a lot more protons around today compared to neutrons.
The result of this process is that the universe at about 20 minutes, has a nucleon content
of around 75% Hydrogen and 25% Helium-4, with very small amount of deuterium, which is an
isotope of hydrogen with an additional neutron, a very small amount of Helium-3 and small
traces of Lithium-9 nuclei. The universe consisted of about 87% protons and 13% neutrons.
So, we see that most of the universe at this point is just protons or Hydrogen nucleons.
Pay attention to the fact that at this point in time it’s all ionized nuclei, so only
the core of the atoms exists – no electrons bound to them.
In order to form neutral atoms, the negatively charged electrons must attach themselves to
the positively charged nucleons to balance out the charges.
The problem is that the universe is still so hot that the electrons can only attach
to the nucleons for a split second before being ripped away because they have so much
energy. This also means that at this point the universe
is still opaque. If you were there, you wouldn’t see anything, because the photons that carry
light would be constantly interact with the nucleons and electrons flying around. They
would not be free to propagate through space. The situation with the electrons and the nucleons
is analogous to a spacecraft trying to orbit a planet. If the craft flies too fast, then
it will fly out of orbit, so it needs to be slow enough for gravity to capture the spacecraft
into an orbit around planet. The same thing with the electron – it can’t
get bound to the nucleon. Now this photon epoch lasts for a very long time – about
380,000 years until the universe cools down to 3000 Kelvin. At this point the electrons
have so little energy left that the electromagnetic force can finally bind them to the nucleons
for good and form stable neutral atoms. This is called recombination.
This also means that the photons are no longer bound in this chaos of positive nucleons and
negative electrons. They are now free to fly unobstructed through the universe. And we
would be able to see this light if we were there in space.
The consequence of this today is that everywhere you look, you can see this first light of
the universe. This is called the cosmic microwave background or CMB. This light was released
as the first stable neutral atoms were formed. So the baby pictures of the universe that
you see here is also the record of the first neutral atoms forming in the universe. I made
a video about the CMB if you want to learn more.
Now the story of how the first atoms in the universe formed, is only the beginning of
the fascinating journey of atoms. It is the story of only how the lightest elements formed
– Hydrogen, helium and Lithium and some isotopes. But as you know, we need a lot more
than that for life to exist. So the next question is, how did the rest
of the elements of the periodic table form, particularly where did Carbon, Oxygen, and
Nitrogen – elements essential for life, come from?
That fascinating story will be the subject of my next video. So, stay tuned for that.
In the meantime, if you want to learn about how atoms which form the molecules that take
part in the rich landscape of chemical reactions, you will love a course called, “The Chemical
Reaction” available on Brilliant, today’s sponsor.
In this course, you’ll learn the fundamentals of chemistry from the perspective of chemical
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It’s different than the usual quantum mechanical approach. And you’ll end up learning and
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Brilliant has a special off for Arvin Ash viewers right now. If you are among the first
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my friend.
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