PARTICLE PHYSICS: A PHYSICS KIT

Transcription

1 FORCE SUMMARY Force charge? baryon number? strangeness? leton number? Range Force carrier article Strong Short range: attractive u to m. Below m, it is reulsive. Gluon Weak No Very short range: W +, W - or Z 0 about m. boson Electromagnetic although it gets weaker as things move aart. Photon For more information on our outreach activities, go to our website or us at h-outreach@qmul.ac.uk PARTICLE PHYSICS: A PHYSICS KIT Design: Lydia Thornley Design Illustrations: Roger Taylor

2 PARTICLE PHYSICS: A PHYSICS KIT THE SMALLEST THINGS THE SMALLEST THINGS SLIGHTLY BIGGER THINGS 3 4 U quark. Down quark. u + 2 / 3 d - 1 / 3 s Strange quark. - 1 / 3 RULES FOR COMBINATIONS INTERACTIONS QUIZ CONSERVATIONS HOW FORCES WORK IN DETAIL: ß DECAY FORCE SUMMARY P Antiu quark. Antidown quark. Antistrange quark. u - 2 / 3 d + 1 / 3 s + 1 / 3 ays to make everything around us. All of the matter we see every day is made of two tyes of quark: u quarks and down quarks. However, there are 6 tyes of quark in total, some of which are only seen inside article accelerators and other hysics exeriments, like the LHC. The other tyes of quark form articles which decay turn into other articles, made of u and down quarks very quickly. Here are the lightest three quarks: u, down and strange, along with their antiarticles. Antiquarks (reresented by a bar above the letter denoting the tye of quark) are articles which are the exact oosite of their artner article: they have the same mass, but they interact with the world in the oosite way to ordinary matter, as they have the oosite electric charge. If antimatter meets with its matter twin, they annihilate, disaearing in also combine with u, down and strange to make articles, but to is too heavy, decaying into other things before it has time to combine with other quarks. Particle Physics: a Physics kit SEPnet Queen Mary, University of London 3

3 SLIGHTLY BIGGER THINGS Baryons Mesons Letons RULES FOR COMBINATIONS: CHARGE n Neutron Proton k + k 0 k - Kaons π π π Pions Any article made of quarks is called a hadron. They come in two tyes: Electron Neutrino Muon Antielectron Positron Antineutrino Antimuon Baryons. These are made of three quarks. A roton, made of two u quarks and a down quark, is a baryon. Its antiarticle is the antiroton, made u of two antiu quarks and an antidown quark. Mesons. These are made of one quark and one antiquark. The π + (a ositively charged ion) contains an u and an antidown quark. The antiarticle is the oosite of the article swaing quarks for antiquarks and vice versa. π - s s - 1 / / 3 ϕ 0 We can t just stick any combinations of articles together to make whatever we like. Quarks combine according to certain rules. Electric. To make a article, the charges of the individual quarks must add u to make a whole number. Particles cannot have fractional charge. So a article with just two u quarks is imossible, because it would have a charge of 4 / 3. ū d - 2 / / 3-1 / 3 There is also a class of articles called letons. These include the electron, and are not made u of quarks in fact we don t think they are made u of anything smaller at all. The muon is like a heavy electron, and the neutrino is a ghostly article which is very light, and doesn t often interact with normal matter. 4 Particle Physics: a Physics kit SEPnet Queen Mary, University of London Particle Physics: a Physics kit SEPnet Queen Mary, University of London 5

4 Red Antired INTERACTIONS QUIZ Proton 0 V RULES FOR COMBINATIONS: COLOUR Lambda Baryon πpion What force is it? Green Blue Antigreen Antiblue Quarks have a strange roerty called colour - they can be red, green or blue, whilst antiquarks are antired, antigreen or antiblue. Any quark can have any colour, although antiquarks must have anticolours. This doesn t refer to a real colour, it s just a (rather odd) name for a roerty, like charge or baryon number. Particles must be colour neutral: that is the colours of the quarks must combine to make white. So a article with three quarks is, as the quark can be red, and the antiquark antired. But if you try to make a article with two quarks and an antiquark, you won t be able to combine the colours to make white, so it isn t a ossible real article. 6 Particle Physics: a Physics kit SEPnet Queen Mary, University of London What force is it? Antimuon Neutrino π+ Pion Here are some interactions between articles. Work out the strangeness, charge and forces involved. Particle Physics: a Physics kit SEPnet Queen Mary, University of London 7

5 CONSERVATIONS When articles interact, they can t just do anything they want. Just like quarks can t combine in any way they like, article interactions must obey certain rules. Particle hysicists call these conservations and there are a lot of them - but here are a few that will be helful to you now. Electric. The charge at the beginning must be the same as the charge at the end. So if the article which decays has a charge of +1, then the charges of whatever it decays into must add u to +1.. This basically says that the number of baryons (articles made of three quarks) must stay the same. Baryons have a baryon number of +1, whereas antibaryons (made of three antiquarks) have a baryon number of -1. This means that you can add a baryon-antibaryon air to one side of a reaction, as their baryon numbers combine to make 0.. Similar to baryon number, but for letons. Electrons, muons and neutrinos have leton number +1 and their antiarticles have leton number -1.. This is like a strange quark number, like baryon or leton number, excet backwards: if a article has one strange quark in it, it has a strangeness of -1. A article with an antistrange has a strangeness of +1. What this is saying is that most of the time, if you start off with a strange quark in the article before it decays, you will end u with one at the end. It s like a chemical reaction: if you start off with 4 oxygens, whatever you get at the end must contain 4 oxygens. However, there is one big excetion to this: the weak force. This force has the weird ability to change one quark into another, an effect which is very imortant in everyday life (see age 10!). If you have a strange quark at the beginning but not the end, you can be sure that the weak force is resonsible! HOW FORCES WORK Reulsion Attraction e Carrier article Carrier article There are four tyes of force that we know about. The one that is the most familiar to you gravity isn t actually very imortant in article hysics, because it is very weak comared to the other three. The three imortant forces are: Electromagnetism. This will be very familiar to you it s why you can stick things to the fridge and watch tv. The strong force. This is the strongest force (unsurrisingly), and is what sticks quarks together inside articles. If the quarks get too close together, the force becomes reulsive, so that the quarks don t collase in on one another. The weak force. This is the only force that can change one tye of quark into another, and only works over very very small distances. Gravity doesn t seem all that weak, but the strong and weak forces are very short range, so we don t really notice them, and things tend to have no overall electric charge, so electromagnetism doesn t make us all stick together. Forces work through the exchange of articles. Imagine throwing a ball to someone. As you throw the ball, you have to move backwards a little and when they catch it, they will move backwards too. This is how reulsion works. Attraction is more difficult to imagine but you can think of it as working the oosite way e e 8 Particle Physics: a Physics kit SEPnet Queen Mary, University of London Particle Physics: a Physics kit SEPnet Queen Mary, University of London 9

6 IN DETAIL: ß DECAY n u d d u d u W - e - ν Earlier, we said that the weak force has the ability to change one quark into a totally different tye of quark, a bit like changing an oxygen atom into something totally different. This might seem a bit strange but in reality, it causes a very well known effect, and one that you have studied a lot. Radioactivity is where one element turns into another element, by emitting radiation, and the most common tye beta decay is controlled by the weak force. In beta decay, a neutron turns into a roton, shooting out an electron in the rocess. To conserve leton number, it must also emit an antineutrino at the same time. But what is actually haening? Take a look at the Feynman diagram a handy way of writing down what is going on in article interactions. One of the down quarks in the neutron is turned into an u quark and becomes a roton. In order to do this, one of the force carrier articles mentioned earlier is released, which quickly turns into an electron and an antineutrino. This tye of decay is called Beta Minus decay, because it emits a negatively charged electron. 10 Particle Physics: a Physics kit SEPnet Queen Mary, University of London Particle Physics: a Physics kit SEPnet Queen Mary, University of London 11