Type of interactions

Animated particle collisions with explanations!

In the DELPHI detector high energy electrons and positrons (the antiparticle of the electron) collide. During the first phase of LEP, the energy of the colliding particles were set to 46.5 GeV each in order to produce the Z⁰ particle which has a mass of 91 GeV. During the second phase of LEP, which started in 1996, the energy of the colliding particles are set such that a pair of W particles can be produced. The mass of W is around 80 GeV, so the energy of each colliding particle has to be at least 80 GeV to be able to produce two W particles.

The single Z⁰ event is easier to start with. The events with two W or Z⁰ particles are more complicated because of the different way the two particles can decay and the many possible combinations. The Z and W particles are produced almost at rest as almost all the collision energy goes into producing the particles. The collision energy is almost entirely transformed into mass. When a particle at rest decays, the decay products go back to back.

In each event many different type of particles can be produced. Some of the most important particles to identify are:

The electron - a charged particle that deposits its energy in the electromagnetic calorimeter
The muon - a charged particle going through all the detectors
The quark and the gluon - give rise to sprays with 10 to 30 particles.

Production and decay of Z⁰

The Z⁰ can decay to almost any pair of quarks or leptons. The exception is the decay into a pair of top quarks as the top quark is too heavy.

Decay into leptons

decay to electrons; two high energy tracks back to back stopping in one of the electromagnetic calorimeters (HPC or FEMC)
decay to muons; two high energy tracks back to back going through the complete DELPHI detector
decay to taus; the tau is very short-lived - its decay products, one or three charged particles will be observed
decay to neutrinos is invisible

Decay into quarks

free quarks can not escape from the collision point due to the strong force between the quarks. The separating, outgoing quarks will give rise to a spray, a jet of particles. Decay to quarks will most of the time give rise to two jets of particles with many particles in each jet.

Short-lived particles - beauty and charm particles

The particles that contain the heavy b or c quark are very short-lived, typically 10^-13 to 10^-12 s. They will therefore decay very close to the collision point. With the high resolution detector (VD) it is possible to observe that some of the charged particles do not come from the collision point but from a point a small distance away. This is the "signature" for the decay of a very short-lived particle like a beauty or a charm particle.

Strange particles

Many particles containing an s quark have lifetimes of the order of 10^-10 s. They can decay in many of the DELPHI detectors. It is relatively easy to observe these decays when they occur in the large volume drift chamber TPC.