Everything Everywhere Daily: History, Science, Geography & More - The Large Hadron Collider
Episode Date: June 24, 2023Straddling the border of Switzerland and France is the largest scientific instrument ever created. It sits in a tunnel 27 kilometers or 17 miles long, at points, it rests 175 meters or 574 feet belo...w the surface, and it cost a whopping €7.5 billion. It consists of thousands of powerful magnets and a vacuum chamber and uses a great deal of energy. With it we can probe the secrets of the basic particles that make up the universe. Learn more about the Large Hadron Collider, how it works, and why it was built on this episode of Everything Everywhere Daily. Sponsors Expedition Unknown Find out the truth behind popular, bizarre legends. Expedition Unknown, a podcast from Discovery, chronicles the adventures of Josh Gates as he investigates unsolved iconic stories across the globe. With direct audio from the hit TV show, you’ll hear Gates explore stories like the disappearance of Amelia Earhart in the South Pacific and the location of Captain Morgan's treasure in Panama. These authentic, roughshod journeys help Gates separate fact from fiction and learn the truth behind these compelling stories. InsideTracker provides a personal health analysis and data-driven wellness guide to help you add years to your life—and life to your years. Choose a plan that best fits your needs to get your comprehensive biomarker analysis, customized Action Plan, and customer-exclusive healthspan resources. For a limited time, Everything Everywhere Daily listeners can get 20% off InsideTracker’s new Ultimate Plan. Visit InsideTracker.com/eed. Subscribe to the podcast! https://link.chtbl.com/EverythingEverywhere?sid=ShowNotes -------------------------------- Executive Producer: Charles Daniel Associate Producers: Peter Bennett & Thor Thomsen Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Learn more about your ad choices. Visit megaphone.fm/adchoices
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Stradling the border of Switzerland and France is the largest scientific instrument ever created.
It sits in a tunnel 27 kilometers or 17 miles long, and at points it rests 174 meters or 575
feet below the surface, and it cost a whopping 7.5 billion euro.
It consists of thousands of powerful magnets, one of the world's largest vacuum chambers,
and uses a great deal of energy.
But with it, we can probe the secrets of the basic particles that make up the universe.
Learn more about the large Hadron Collider,
how it works and why it was built
on this episode of Everything Everywhere Daily.
What if your perceptions about the past were wrong?
ThruLine is a podcast that takes you back in time
to uncover the parts of the story that may have gone unnoticed.
It effectively turned day into night.
And how it shaped the world now.
Time travel with us every week on the ThruLine podcast from NPR.
Before we get into the history of the Large Hadron Collider, it's necessary to first talk about
what particle accelerators do and why they're used.
As the name would suggest, particle accelerators accelerate particles.
Technically speaking, a particle accelerator doesn't have to be very expensive or sophisticated.
Certain particles have an electrical charge, electrons, protons, and their antimatter equivalents,
positrons and antiprotons.
If you take a particle with an electrical charge, so let's say an electron with an
negative charge. It'll be repelled by anything with a negative charge and attracted to something
with a positive charge. Using this property of charge particles, you can pretty easily create a
device that accelerates them. You create two metal plates with holes in them, one as a negative charge
and one as a positive charge. Put an electron into the hole of the plate with a negative charge
and it will be repelled away and also attracted to the plate with a positive charge. You can then
set up another one of these for when the electron passes through the hole in the positively charged
plate. Put enough of these in series, and you can accelerate an electron to very high speeds.
If you can remember old television sets that had cathode ray tubes, those were technically
particle accelerators. Electrons were shot at a screen, which is how an image was made. There's a
good chance there is even a more powerful particle accelerator not far from where you are right now.
Particle accelerators have industrial uses in sterilizing medical equipment, cancer treatments, and
viewing inside objects.
These, however, are a far cry from what physicists use particle accelerators for.
In the late 19th and early 20th centuries, physicists discovered most of what we know about the
basic structure of the atom. They learned first that atoms existed, and that there were negatively
charged things called electrons. They also then figured out that an atom had a nucleus that
consisted of positively charged protons and neutrally charged neutrons. This is what most of you
probably learned about the atom in physics class in high school. However, they soon
found out that there was more to it. In 1936, while studying high-energy cosmic rays,
researchers at Caltech found that there were other subatomic particles. They discovered a
particle that they dubbed a muon. Mewons behaved differently than either electrons or protons when
they passed through a magnetic field. Mewons were short-lived and created when high-energy
cosmic rays from space collided with other particles in the atmosphere. The problem with
observing particles created by cosmic rays is that you really couldn't control what was happening.
The ability to study these particles was highly random. The obvious solution was to study these
particles in a more controlled environment, to recreate the conditions of high-energy cosmic rays,
but in the laboratory. If you remember back to my episode on cosmic rays, they are tiny
subatomic particles that travel near the speed of light at extremely high energies. Some come from
our sun, but others may have traveled from other parts of our galaxy, or even from outside our
galaxy. The tool that was used to do this was a particle accelerator. The first particle accelerator
for scientific use was built in 1930 before the discovery of the muon. Ernest O. Lawrence at the
University of California, Berkeley, created a device known as a cyclotron. A cyclotron is a spiral that
accelerates particles from the center and holds them in place along the spiral using magnetic fields.
Lawrence was given the 1939 Nobel Prize in Physics for the invention of the cyclotron.
The cyclotron was basically a first-generation particle accelerator.
The amount of energy that could be put into a particle, in other words, how much it could be accelerated,
was limited to the length of the spiral and by the maximum electrical potential that could be achieved in the accelerating region.
This problem was solved in the 1950s with the development of the synchrotron.
A synchrotron is a particle accelerator that is a circle.
There are two parts to a synchrotron. One part is the acceleration section. This section, as I just described, uses electrical potential to accelerate a particle. The rest of the synchrotron consists of magnets that guide the particle along a curved path right back to the acceleration section. This allows the particle to loop around and around, picking up energy the entire way. So how much energy are we talking about? In particle physics, energy is usually given in the form of electron volts.
An electron volt is a very small unit of energy, which is defined as the energy gained or lost by an electron
when it moves through an electrical potential difference of one volt.
To put this in everyday terms, one electron volt is about one ten quintillions of a joule of energy.
And one jewel of energy is approximately the amount of energy required to lift an apple up about one meter in Earth's gravity.
So a single electron volt is really, really small.
The amount of energy in a cosmic ray can be anywhere from 1 billion electron volts to 8 trillion electron volts.
Naturally, lower energy cosmic rays are more common and the very high-energy cosmic rays are very rare.
The more energy a particle has, the greater the collision when it hits something,
and the greater the ability to smash apart the particle, releasing subatomic particles
that couldn't be released at lower energies.
In order to get these very high energies, you need a larger area for acceleration,
which means you need a very large synchrotron.
Roughly speaking, the larger the particle accelerator, the higher the energy particle you can create,
and the more you will be able to see in the resulting collisions.
This has resulted in increasingly large particle accelerators over time.
By the 1990s, the largest particle accelerator in the world was the Tevatron,
located at Fermilab outside of Chicago, Illinois.
It had a circumference of 6.3 kilometers and could accelerate particles to 900 billion electron
volts. But there was a need for even larger particle accelerators, but at this scale you entered
the realm of extremely big science projects that could only be funded by governments. The cost of
something larger would run into the billions of dollars and would be on a par with the cost of
running a space program. In the 1980s, the United States approved funding for the superconducting
supercollider, or SSC. It would, by a wide margin, have been the biggest particle accelerator
in the world, with a circumference of 87.1 kilometers or 54.1 miles. Over 22.5 kilometers, or 14 miles of
tunnel had been bored in Texas at a cost of $2 billion when the program was canceled by the U.S.
Congress in 1993. The cancellation of the SSC left a massive hole in the world of high-energy physics,
and the Europeans picked up the gauntlet. The European Organization for Nuclear Research,
also known as CERN, was launched in 1954. They operated the Large Electron Positron Collider,
which operated from 1989 to 2000. It was one of the largest particle accelerators in the world,
but it eventually reached its limits for what it could do at 209 billion electron volts.
In 1994, just a year after the SSC was canceled in the United States,
CERN began working on feasibility plans for a new particle accelerator,
which they dubbed the Large Hadron Collider.
Here I should take a moment to note what a hadron is. A hadron is a subatomic particle that is made up of other smaller subatomic particles called quarks. Because they are made up of smaller particles, they are uniquely suited to be studied in particle collisions. A more in depth discussion of what is called the standard model of particle physics I will do in a future episode. Approval for the LHC was given in 1995 with a budget of 2.6 billion Swiss francs. The large Hadron Collider was to be 27 kilometers or 7,000.
17 miles in circumference, almost five times the size of the previous largest supercollider.
It lies in both Switzerland and France and actually makes four border crossings along its loop.
Construction of the project took years, and there were various setbacks, including problems
with the superconducting magnets and leaks in the vacuum-sealed tube.
However, on September 10, 2008, the first beam was sent around the collider.
These were actually at very low speeds, and it took almost an hour to travel the complete
circuit. On November 9th, 2009, they managed to accelerate a particle beam to 1.18 trillion electron
volts, beating the record previously set by the Tevatron. 2010 and 2011 saw increased energies
in their particle beams, and as they continued to run collisions, teams of researchers
began to see the thing that they hoped to find. Proving or disproving the existence of the Higgs
boson particle was one of the primary reasons why the Large Hadron Collider was built. In 2012, it
announced that they had conclusive proof of the existence of the Higgs boson particle.
Two different teams running different experiments and kept apart from each other so they couldn't
share information came to the same conclusion.
The confidence of the discovery was that it could only be one in three million odds that it was
just chance.
The 2013 Nobel Prize was awarded for the discovery of the Higgs boson.
One of the big debates in awarding the prize was who to award it to, as there were literally
tens of thousands of people who took part in the discovery.
From 2013 to 2015, the Large Hadron Collider was shut down for upgrades.
When it was fired back up in 2015, it was able to fire protons at 6.5 trillion electron volts,
and then have them collide with each other with a total energy of 13 trillion electron volts.
It was shut down again from 2018 to 2022, and as of the time of this recording, it's operational again.
It's scheduled a shutdown for more upgrades in 2026.
One of its primary objectives now is searching for a potential fifth fundamental force in nature.
Despite being the most powerful accelerator on Earth, with plenty of years of operation ahead of it,
there is now talk of building a successor to the LHC.
A new proposed CERN particle accelerator would be a hundred kilometers in circumference
and almost four times the size of the LHC.
They would be able to accelerate particles to over six times the energy of the LHC,
and much of it would be buried in a tunnel underneath Lake Geneva.
The Chinese government has also proposed its own 100-kilometer particle accelerator
known as the Circular Electron Positron Collider.
There's even been talk of restarting the American superconducting supercollider,
but the odds of that happening are pretty slim.
There are still many unanswered questions in physics that might require an even more powerful particle accelerator to answer.
These include the mystery of dark matter and dark energy,
the prevalence of matter over antimatter in the universe, and the nature of the neutrino.
The bigger these particle accelerators get, the more money they require, and the more difficult
it will be to get these projects approved. But wherever and whenever these future super particle
accelerators are built, they may help unlock the remaining secrets of the universe.
The executive producer of Everything Everywhere Daily is Charles Daniel. The associate producers
are Thor Thompson and Peter Bennett. I just want to thank everyone, including the show's
producers who support the show over on Patreon.
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