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Large Hadron Collider

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Map of the Large Hadron Collider at CERN

The Large Hadron Collider (LHC) is the world's biggest and most powerful particle accelerator. It was built by the European Organization for Nuclear Research (CERN). It is a giant circular tunnel built underground. The tunnel is 17 miles (27 kilometers) long, and between 50 and 175 meters below the ground.[1] It lies beneath the border of Switzerland and France. 10,000 scientists and engineers from over 100 different countries worked together in the making of this project, and it cost 10.4 billion Swiss francs ($10 billion) to build.[2] It is now the largest and most complicated experimental research facility in the world.

As its name states, the research at the LHC involves the collision of hadrons. A hadron is a particle which consists of a number of quarks held together by the subatomic strong force. Protons and neutrons are examples of a hadron. The LHC primarily uses the collision of protons in its experiments.[3] Protons are parts of atoms with a positive charge. The LHC accelerates these protons through the tunnel until they reach nearly the speed of light. [1] Different protons are directed through the tunnel in opposite directions. When they collide, they create conditions similar to the early universe.[3]

The LHC attempts to study elementary particles and the ways they interact. It has already taught us a lot about quantum physics, and researchers are hoping to learn a lot more about the structure of space and time. The observations researchers are able to make can help us learn what the universe might have been like within milliseconds after the big bang.

The LHC ionizes Hydrogen atoms in order to get the protons they use. A Hydrogen atom consists of only one proton and one electron. When they ionize the atoms, they are removing the one electron to give it a net positive charge. The Hydrogen protons are then directed through the circle by electromagnets. In order for the magnets to be strong enough, it must be very cold. The inside of the tunnel is cooled by liquid helium. They keep the temperature at just above absolute zero. The protons hit one another at close to the speed of light and convert to energy using E=mc2. It then reverses and creates mass. At the collision site, there are four layers of detectors. The explosion passes through each layer and each detector records a different stage of the reaction.

When the particles hit each other, their energy is converted into many different particles, and sensitive detectors keep track of the pieces that are created. By looking carefully at the detector data, scientists can study what the particles are made of and how the particles interact. This is the only way to see some particles because very high energy is needed to create them. The LHC's particle collisions have the energy needed.[1]

The LHC has three main parts to it. There is the particle accelerator, the four detectors, and the Grid. The accelerator creates the collision, but the results cannot be directly observed. The detectors turn it into useable data. This data is then sent to the Grid. The Grid is what the researchers use to interpret the data. It is a network of computers. There are 170 locations in 36 different countries which are filled with regular desktop computers. All of these computers are connected, and together they act as a supercomputer. The LHC's Grid is considered the most powerful supercomputer ever built. The computers share processing power and data storage space. [4]

The Grid is very powerful, but it is only able to take in about one percent of the data it receives from the detectors. [5] Its limitations have motivated attempts at creating quantum computers, which could use what the LHC has taught us about quantum mechanics in order to make faster computers.

Scientists have recently used the LHC to find the Higgs boson. A boson is an elementary particle that carries force, as opposed to fermions which carry matter. The Higgs boson explains why particles have mass. For a long time, scientists couldn't explain why some particles had mass and others didn't. For example, photons don't have mass. The LHC's discovery of the Higgs boson proved the existence of the Higgs field. The Higgs field is an invisible field that exists everywhere in the universe. When particles pass through the field, they get mass.[6] The Higgs boson is the last particle predicted to exist by the Standard Model. Its discovery helps scientists show that the Standard Model is right and show what the universe is made of.

Some people think the LHC would create a black hole, which would be very dangerous. There are two reasons not to be worried. The first is that the LHC won't do anything that the cosmic rays that hit the Earth every day don't do, and these rays do not create black holes. The second reason is that even if the LHC did make black holes, they would be very tiny. The smaller a black hole is, the shorter its life. Very tiny black holes would die and turn into energy before they could hurt people.[7]

The LHC was first used on September 10, 2008, but it did not work because a cooling system broke, which was important for the magnets that help to move the charged particles. This caused part of the facility to collapse. The winter shutdown meant that it was not used again until November 2009. While it was being repaired, scientists used the Tevatron to try and find the Higgs Boson. When the LHC was restarted in November 2009, it set a new speed record by accelerating protons to 1.18 TeV (teraelectronvolt, or trillion electronvolt).[2] On March 30 2010, the LHC created a collison at 3.5 TeV.[1]


  1. 1.0 1.1 1.2 1.3 "LHC Machine Outreach" (in English). Retrieved 2010-05-02.
  2. 2.0 2.1 "Large Hadron Collider: Best- and Worst- Case Scenarios" (in English). Wired Magazine. September 9, 2008. Retrieved 2010-01-31.
  3. 3.0 3.1 Science and Technlogy Facilities Council. "STFC Web Site." Large Hadron Collider. Research Coucils UK, n.d. Web. 12 May 2014. <>.
  4. "CERN Accelerating science." Welcome to the Worldwide LHC Computing Grid. N.p., n.d. Web. 14 May 2014. <>.
  5. "GridPP." GridPP News. N.p., n.d. Web. 14 May 2014. <>.
  6. Adrian Cho (13 July 2012). "Higgs Boson Makes Its Debut After Decades-Long Search". Science 337 (6091): 141–143.
  7. "The safety of the LHC". CERN. Retrieved 2008-3-9.

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