Why We Can Exist | Crash Course Pods: The Universe #2

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Introduction (00:00:00)

The fundamental forces of nature are energy-dependent, meaning they behave differently at extremely high energy environments compared to the universe's current temperature.
Particle colliders are scientific instruments used to create high energy environments by colliding particles together.

Particle colliders are primarily designed to recreate the conditions of the early universe when the laws of physics were different due to high temperature and density.
Some early particle colliders were used to study the internal structure of particles, such as protons, revealing their complex nature.

Protons and neutrons are composed of fundamental particles called quarks, which come in six types: up, down, strange, charm, top, and bottom.
A proton is made of two up quarks and a down quark, while a neutron is made of two down quarks and an up quark.
The mass of a proton is much greater than the combined masses of its constituent quarks due to the energy of quark confinement and the constant creation and annihilation of quark-antiquark pairs within it.
Protons are constantly in a state of superposition, with particles coming in and out of existence.
Despite their complexity, protons are essential components of atoms and all living organisms.

The properties of the universe and physics were different in the early universe due to high temperatures and energies, causing fundamental forces to behave differently.
Fundamental forces of nature include electromagnetism, the weak nuclear force, and the strong nuclear force.
The strength of fundamental forces changes with energy, and at extremely high energies, they all become approximately equal in strength, a phenomenon known as Grand Unification.
Grand unification theory attempts to explain why the forces of nature have different strengths and how they interact.

Physicists aim to simplify complex phenomena by finding underlying unifications, such as discovering that different elements are composed of the same fundamental particles.
Grand unified theories propose that the four fundamental forces (excluding gravity) are the same force appearing differently due to low-energy perspectives.
Gravity behaves differently from the other forces and is not energy-dependent like they are, remaining weaker and mathematically distinct.
String theory and Loop quantum gravity are potential theories that may explain how gravity works together with other forces in the universe.
Quantum gravity is necessary to comprehend the earliest moments of the universe when all forces, including gravity, were highly influential.

The Higgs field is an energy field that exists throughout space and controls how physics works in the universe.
In the early universe, the Higgs field had a different value, allowing different particles and forces to exist.
When the value of the Higgs field changed, it altered the set of particles and forces, enabling electricity and magnetism to be distinct from the weak nuclear force and allowing certain particles to gain mass.
The Higgs boson, associated with the Higgs field, confirmed its existence.
The change in the Higgs field's value around 20 picoseconds after the Big Bang allowed the universe to evolve into its current form.
This change enabled particles to gain mass, leading to the formation of atoms and molecules.
Before the Higgs field changed, the universe was in a hot, soupy state with quarks and gluons mixed together.
As the universe cooled, quarks and gluons formed protons and neutrons, resulting in the creation of hydrogen, helium, and lithium through Big Bang nucleosynthesis.

Scientists have been able to observe the Higgs boson, confirming its existence and its role in the formation of matter.
By recreating the conditions of the early universe in particle colliders, scientists can study its evolution and observe various phase transitions and the formation of subatomic particles.
Experiments have allowed scientists to trace back the universe's history to a trillionth of a second after its beginning.
The theory of the Big Bang suggests the Universe was hot and dense in its early stages, and we have evidence to support this.
Humans have made incredible progress in describing the first moments of the Universe, providing valuable insights into our origins.