Quark Physics

What is the physics behind quarks?

Quarks are involved in several physical processes. They make up the mass of the universe, as they are the elemental particles that make up the protons and neutrons and give them an electrical charge. Quarks also form special hadrons such as the Pion plus and Kaon plus. And quarks are present in beta decay, which is a form of radiation.

Hadron charge and quarks

Protons and neutrons both consist of three quarks whose symbol is qqq. The combination of up and down quarks tells you which kind of particle you are dealing with. To know which particle a quark makes, you need to add three quarks in such a way that you obtain a fundamental charge of 1 for a proton or 0 for a neutron, as in the following examples.

Pion plus and kaon plus hadrons

Quarks can combine themselves with an antiquark, creating a matter-antimatter duo, as in the case of the pion plus and kaon plus hadrons.

• Pion plus: a combination of an up quark that has a charge of + ⅔ and an anti-down quark with a charge of + ⅓ and thus a total charge of 1.
• Kaon plus: a combination of an up quark that has a charge of + ⅔ and a strange antiquark with a charge of + ⅓ and thus a total charge of 1.

The pion plus and kaon plus quarks have a baryon number of 0, indicating that they are a combination of matter and antimatter.

Quarks and beta decay

If a nucleus has too many neutrons or protons, a process called beta decay can begin. Beta decay transforms a proton into a neutron or a neutron into a proton. Protons consist of two up quarks and one down quark (udu), while neutrons consist of two down and one up quark (dud).

In the case of a neutron to proton conversion, one down quark must convert itself into an up quark. This conversion includes the release of an electron, which takes away the negative charge, and an antineutrino, as shown below:

${}_0^{1}n{\to }_1^{1}p{+}_{-1}^{0}e+\overline{v_{\epsilon }}$

You can observe the conservation in the equation. The neutron has a baryon number of 1 in the upper corner and 0 as its fundamental charge in the bottom corner.

The result of the decay must be a proton with a charge of 1 and an electron with a charge of -1. In this process, an antineutrino is emitted as well.

$\text{charge conservation = neutron charge = proton charge + electron charges}$

Weak interaction and quarks

The process that converts a neutron into a proton is called the weak interaction process. There are four weak interaction processes, as listed below.

In the four processes, a W+ or W- boson particle acts as a carrier of the energy.

Feynman diagram and quarks

The Feynman diagram is a way to show the interaction between particles as they emit or absorb energy while creating other particles. Let us consider the example of the beta decay of a neutron into a proton, as shown below:

${}_0^{1}n{\to }_1^{1}p{+}_{-1}^{0}e+\overline{v_{\epsilon }}$

The Feynman diagram for this is:

Strange quarks and the strange number

High energy photons such as gamma rays can collide with particles, emitting other particles and radiation. In the earth’s atmosphere, they inject energy into molecules of air, creating strange quarks. However, the particles created do not separate themselves into smaller particles as quickly as scientists expected. This effect was explained by a new property called strangeness, which is indicated by the strange number. Strange numbers only change during weak force interactions.