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Transcript
How Are Electric And Magnetic Fields Used To Steer Particles In The Large Hadron Collider? Effect of a Uniform Electric Field on the Motion of Charged Particles In an electrical field the motion of a charged particle will experience a constant upwards force with a constant vertical acceleration and a constant horizontal velocity. Because the field is uniform meaning the lines in the field will remain the same throughout the field – parallel and equispaced. Electric Field Strength: Uniform Electric Field Strength: E = electric field strength V = the pd between the plates F = force acting in Newton’s d = the distance separating the plates. q = the charge in coulombs Units of E: NC-1 or Vm-1 Units of E: NC-1 or Vm-1 Effect of a Uniform Magnetic Field on the Motion of Charged Particles When a charged particle enters a magnetic field it will be forced to change direction. If it stays in the field it will continue to change direction and will move in a circle. The force produced will provide the centripetal force on the moving particle. Force on a charged particle in a magnetic field equation: F = B q v sin θ F = force (N) B = magnetic field strength (T) q = charge on the particle (C) v = velocity of the particle (m/s) (Angle θ is between the direction of the beam and the magnetic field direction) Motion of Charged Particles • • Charged particles such as electrons or protons are accelerated by an electric field to speeds almost equal to the speed of light. They are made to collide with one another and in such collisions some of the kinetic energy is turned into matter - new particles are created. The simplest particle accelerator is the electron gun. The electrons are produced by heating a cathode. The electrons 'boil' off from the cathode and are accelerated towards an anode with a small hole in it. Many of the electrons pass through the hole forming an electron ray (cathode ray). The energy of the electrons is found using Energy = eV. Linear Accelerometers Cyclotrons • The length limitation can be overcome by making the charged particles follow a circular path. In a cyclotron charged particles are accelerated across the gap between two 'D' shaped electrodes. Meanwhile a perpendicular magnetic field moves the particles in a circle. The radius of the circle increases after each successive acceleration, so the path spirals out from the source at the centre to the target on the outside. Large Hadron Collider
