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The Large Hadron Collider has been used to find out what matter is fundamentally made of, and how the universe was created. EPA/Martial Triezzini

Explainer: quarks

One of humanity’s eternal questions surrounds what we are fundamentally made of. Many ancient philosophies believed in a set of classical elements: from water, air, fire and earth of ancient Greeks; to water, fire, earth, metal and wood of East Asian Wu-Xing thought.

Physicists today believe that matter is made up of twelve fundamental particles - quarks and leptons - that have no substructure and cannot be broken down into smaller particles. Quarks and leptons interact via four forces to make the universe we know today.

How these particles work to make matter

Six types of quarks have so far been experimentally confirmed, given the names of “up”, “down”, “strange”, “charm”, “bottom” and “top”, in ascending order of mass.

There also are six types of leptons, three electrically charged ones: “electron”, “muon” and “tauon”; and three electrically neutral ones called neutrinos. Each of the three neutrinos pair up with one of the charged leptons and are called “electron neutrino”, “muon neutrino” and “tau neutrino”, respectively.

These twelve elementary particles are mediated by exchanges of another type of particle referred to as a force mediator. Today, four types of elementary force mediators are known, namely the “gluon”, “photon”, “graviton” and “weak bosons”.

Actually, the graviton has not yet been experimentally confirmed, but many physicists assume that this mediator exists.

The quark structure of the proton. Arpad Horvath

In an atomic nucleus, a proton is made up of two up quarks and one down quark, and a neutron is composed of one up quark and two down quarks. The force that binds three quarks in a proton or a neutron is called the strong force, and this force is due to exchanges of gluons.

An atomic nucleus constitutes an atom together with electrons orbiting around it. The relation between the nucleus and electrons resembles the one between the sun and planets in the solar system.

The quark structure of the neutron. Arpad Horvath

The nucleus and the electrons are attracted to each other, exchanging photons. The force between the nucleus and electrons is the electromagnetic force.

Many atoms constitute objects in our everyday life as well as much bigger components of the universe such as stars and galaxies. The force dominating this level of macroscopic phenomena is gravity, intermediated by gravitons.

In the centre of stars, huge energy is generated by nuclear fusion being mediated by weak bosons. This energy makes the universe bright. In nuclear fusion, a down quark is changed to an up quark by the weak force. Stars are luminous because the fundamental building blocks are changing their types and providing energy.

Quarks like to hang in groups

Although most physicists believe that quarks are the fundamental building blocks which make up the universe, no one has observed an isolated quark on its own. This is due to the nature of the strong force.

Like a nucleus and an electron that attract each other due to their electrical charges, quarks are combined together by their colour charges. The strong force is a force that works between colour charges. Just like there are two types of electrical charges, there are three types of colour charges - “red”, “blue” and “green” – analogous to the primary colours of light. The strong force forces quarks to be in a “white” state.

If you have learnt the theory of the elementary colours of light, you can remember that the superposition of the three elementary colours ends up with white. This is the reason why a proton and a neutron consist of three quarks. In a proton and a neutron, one quark has a red colour, another has a blue colour and the third one has a green colour.

As a consequence of the fact that the strong force prohibits non-white states, no one has succeeded in isolating a quark. This phenomenon is called the quark confinement.

The existence of quarks has been established by a number of experiments, but should you find a way to isolate an individual quark, you would be in line for a Nobel Prize!

Cutting edge

Some physics theorists seriously think about the possibility that in the primordial universe (around 10-6 seconds after the Big Bang), another phase was realised in which quarks and gluons were flying as free particles. This phase is called the Quark-gluon plasma (QGP) phase.

How the Large Hadron Collider works to discover the origins of our universe.

Scientists have been trying to reproduce the QGP phase by colliding heavy ions using powerful particle accelerators like the Large Hadron Collider (LHC) in Geneva and the Relativistic Heavy Ion Collider (RHIC) in New York.

So far, the RHIC has indicated that the creation of a QGP phase is possible at the hottest temperature ever reached in a laboratory (it is four trillion degrees celsius, 250,000 times hotter than the centre of the sun).

Though quarks are the elementary particles in physics today, there have been trials to see if there is structure within them. If one observes the structure of a quark, it means that quark is no longer elementary but a composite particle consisting of more fundamental particles.

One way to see the structure would be to follow the manner of Rutherford’s famous experiment performed 100 years ago. He shot alpha particles at a gold foil and observed that some of them were deflected at a very large angle showing the existence of a hard core within an atom.

Likewise, an unexpected large deflection of incident particles in high-energy collisions might mean the discovery of the structure of quarks. The current most powerful particle accelerator is the LHC, which has been colliding protons at the centre of mass energy of eight TeV (106 times higher than the energy of alpha particles).

As of yesterday, the LHC has shut down for an upgrade, but it will be back with its energy doubled in 2015. So stay tuned!

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