Cern sverige

The research programme at CERN covers topics from the basic structure of matter to cosmic rays, and from the Standard Model to supersymmetry. CERN's main focus is particle physics — the study of the fundamental constituents of matter — but the physics programme at the laboratory is much broader, ranging from nuclear to high-energy physics, from studies of antimatter to the possible effects of cosmic rays on clouds.

Since the s, particle physicists have described the fundamental structure of matter using an elegant series of equations called the Standard Model. The model describes how everything that they observe in the universe is made from a few basic blocks called fundamental particles, governed by four forces. Physicists at CERN use the world's most powerful particle accelerators and detectors to test the predictions and limits of the Standard Model.

Over the years it has explained many experimental results and precisely predicted a range of phenomena, such that today it is considered a well-tested physics theory. Why is gravity so weak? Why is there more matter than antimatter in the universe? Is there more exotic physics waiting to be discovered at higher energies? Will we discover evidence for a theory called supersymmetry at the LHC?

Or understand the Higgs boson that gives particles mass? All matter except dark matter is made of molecules, which are themselves made of atoms. Inside the atoms, there are electrons spinning around the nucleus. The nucleus itself is generally made of protons and neutrons but even these are composite objects. Inside the protons and neutrons, we find the quarks, but these appear to be indivisible, just like the electrons.

Home: CERN

Quarks and electrons are some of the elementary particles we study at CERN and in other laboratories. But physicists have found more of these elementary particles in various experiments, so many in fact that researchers needed to organize them, just like Mendeleev did with his periodic table. This is summarized in a concise theoretical model called the Standard Model.

Today, we have a very good idea of what matter is made of, how it all holds together and how these particles interact with each other. Physics The research programme at CERN covers topics from the basic structure of matter to cosmic rays, and from the Standard Model to supersymmetry. Image: CERN.

Featured resources

Physicists at CERN are looking for answers to these questions and more — find out more below. Particles and forces Scientists at CERN are trying to find out what the smallest building blocks of matter are. Standard model. Higgs Boson.

CERN - Wikipedia

W boson. Z boson. Understanding our universe. The early universe. Heavy Ions and Quark Gluon Plasma.

Cern accelerator CERN, the European Organization for Nuclear Research, is one of the world’s largest and most respected centres for scientific research.

Cern synonym CERN (franskt uttal: ['sɛʁn]) (fullständigt namn på franska: Organisation européenne pour la recherche nucléaire och på engelska: European Organization for Nuclear Research) (svensk översättning: Europeiska organisationen för kärnforskning), är världens största partikelfysiklaboratorium, beläget i Genèves förorter i Schweiz, på gränsen till Fr.

Cern labb Sweden.

Cern partikelaccelerator The CERN convention was signed in by the 12 founding states Belgium, Denmark, France, the Federal Republic of Germany, Greece, Italy, the Netherlands, Norway, Sweden, Switzerland, the United Kingdom and Yugoslavia, and entered into force on 29 September

Matter-antimatter asymmetry. Dark Matter. Cosmic rays: particles from outer space. Unified forces. Extra dimensions, gravitons, and tiny black h