A magnetic horn or neutrino horn (also known as the Van der Meer horn) is a high-current, pulsed focusing device, invented by the Dutch physicist Simon van der Meer in CERN, that selects pions and focuses them into a sharp beam. The original application of the magnetic horn was in the context of neutrino physics, where beams of pions have to be tightly focused. When the pions then decay into muons and neutrinos or antineutrinos, a focused neutrino beam is obtained.
Production of a neutrino beam generally involves directing protons onto a fixed target of solid material. The protons interact strongly with the nuclei in the target, producing a variety of secondary hadrons. The proton beam energy and target material are chosen so that these hadrons are mostly pions and kaons. Both of these particles' decays produce neutrinos. However, without a neutrino horn, the resulting neutrino beam is very wide, both geometrically and in energy spread. This is because the secondary particles are produced at a variety of angles and energies and then when they decay, the neutrinos are again produced at a variety of angles and energies.
The neutrinos themselves cannot be focused with electric or magnetic fields because they are electrically neutral. Instead, one or more magnetic horns can be used to focus the secondary particles. The shape of the horn and strength of the magnetic field can be tuned to select a range of particle energies that are to be best focused. In this way, the resulting neutrino beam is both geometrically focused and given a chosen range of energies. Note however that the decays of the secondary hadrons still impart some random direction to the neutrinos, so the beam will always spread to some degree no matter how well the horn works.
