In this part of the particle physics blog, we will talk about antimatter, the standard model and its constituents. Keep reading...
What is Anti-matter?
In the early decades of the 20th century, scientists discovered a certain type of substance that questioned how our matter-filled universe could exist. This discovery was called anti-matter. In 1928, scientist Paul Dirac came up with a solution to describe how electrons behaved near the speed of light. In his equation, he always found that there were two answers, leading him to speculate a different type of matter than our own.
Anti-matter, as the name suggests is the opposite of normal matter. For example- an anti-electron or positron has a charge of positive 1 instead of negative 1. However, this positron would have the same mass and spin as the electron. Just 4 years later, the positron was captured by Carl Anderson, proving Dirac's theory.
However, there is a problem, when matter and anti-matter come together they annihilate. This raises the question about how was there any matter in the first place? Since the laws of Physics do not have any preference, matter and anti-matter must have formed in equal quantities at the big bang. The question is what happened to all the anti-matter? Scientists are still unsure, but I hope we have an answer soon.
What are the fundamental particles?
Let's assume a pencil. When we zoom into its lead, we see rows and rows of Carbon atoms. Zooming in further, we see the nucleus containing protons and neutrons surrounded by a cloud of electrons. electrons are fundamental particles but, protons and neutrons are not. They each contain quarks held together by a gluon field. These are the fundamental particles along with a few more. Together, they form the Standard Model.
What is the standard Model?
The standard Model is a collection of all the known types of fundamental particles in the universe. They are divided into Matter Particles(Fermions) and force particles(Bosons). The Fermions are further divided into quarks and leptons.
Matter Particles
All matter around us is made of elementary particles, the building blocks of matter. These particles occur in two basic types called quarks and leptons. Each group consists of six particles, which are related in pairs, or “generations”. The lightest and most stable particles make up the first generation, whereas the heavier and less stable particles belong to the second and third generations. All stable matter in the universe is made from particles that belong to the first generation; any heavier particles quickly decay to more stable ones. The six quarks are paired in three generations – the “up quark” and the “down quark” form the first generation, followed by the “charm quark” and “strange quark”, then the “top quark” and “bottom (or beauty) quark”. Quarks also come in three different “colours” and only mix in such ways as to form colourless objects. The six leptons are similarly arranged in three generations – the “electron” and the “electron neutrino”, the “muon” and the “muon neutrino”, and the “tau” and the “tau neutrino”. The electron, the muon and the tau all have an electric charge and a sizeable mass, whereas the neutrinos are electrically neutral and have very little mass.
Force Particles
There are four fundamental forces at work in the universe: the strong force, the weak force, the electromagnetic force, and the gravitational force. They work over different ranges and have different strengths. Gravity is the weakest but it has an infinite range. The electromagnetic force also has infinite range but it is many times stronger than gravity. The weak and strong forces are effective only over a very short range and dominate only at the level of subatomic particles. Despite its name, the weak force is much stronger than gravity but it is indeed the weakest of the other three. The strong force, as the name suggests, is the strongest of all four fundamental interactions.
Three of the fundamental forces result from the exchange of force-carrier particles, which belong to a broader group called “bosons”. Particles of matter transfer discrete amounts of energy by exchanging bosons with each other. Each fundamental force has its own corresponding boson – the strong force is carried by the “gluon”, the electromagnetic force is carried by the “photon”, and the “W and Z bosons” are responsible for the weak force. Although not yet found, the “graviton” should be the corresponding force-carrying particle of gravity. The Standard Model includes the electromagnetic, strong and weak forces and all their carrier particles, and explains well how these forces act on all of the matter particles. However, the most familiar force in our everyday lives, gravity, is not part of the Standard Model, as fitting gravity comfortably into this framework has proved to be a difficult challenge. The quantum theory used to describe the micro world, and the general theory of relativity used to describe the macro world, are difficult to fit into a single framework. No one has managed to make the two mathematically compatible in the context of the Standard Model. But luckily for particle physics, when it comes to the minuscule scale of particles, the effect of gravity is so weak as to be negligible. Only when the matter is in bulk, at the scale of the human body or of the planets, for example, does the effect of gravity dominate. So the Standard Model still works well despite its reluctant exclusion of one of the fundamental forces.
very good