8. Magnetic fields
... Consider the mass spectrometer shown this Figure. The magnitude of the electric field between the plates of the velocity selector is 2.5 103 V/m, and the magnetic field in both the velocity selector and the deflection chamber has a magnitude of 0.035 T. Calculate the radius of the path for a singly ...
... Consider the mass spectrometer shown this Figure. The magnitude of the electric field between the plates of the velocity selector is 2.5 103 V/m, and the magnetic field in both the velocity selector and the deflection chamber has a magnitude of 0.035 T. Calculate the radius of the path for a singly ...
Physics: Magnets - John Madejski Academy
... Permanent or Induced Magnets Permanent magnets produce their own magnetic field. Induced magnets are made from magnetic materials (eg. iron, steel, nickel, cobalt). They turn into a magnet when held in a magnetic field. Magnetic materials will always be attracted to a magnet. ...
... Permanent or Induced Magnets Permanent magnets produce their own magnetic field. Induced magnets are made from magnetic materials (eg. iron, steel, nickel, cobalt). They turn into a magnet when held in a magnetic field. Magnetic materials will always be attracted to a magnet. ...
Magnets - John Madejski Academy
... Permanent or Induced Magnets Permanent magnets produce their own magnetic field. Induced magnets are made from magnetic materials (eg. iron, steel, nickel, cobalt). They turn into a magnet when held in a magnetic field. Magnetic materials will always be attracted to a magnet. ...
... Permanent or Induced Magnets Permanent magnets produce their own magnetic field. Induced magnets are made from magnetic materials (eg. iron, steel, nickel, cobalt). They turn into a magnet when held in a magnetic field. Magnetic materials will always be attracted to a magnet. ...
Diapositiva 1
... produced by a magnet has similar pattern to the electric field lines produced by an electric dipole. The main difference is that the magnetic field lines are closed loop (they have no origin and no ending point) while electric field lines always originate from positive charges and end on negative ch ...
... produced by a magnet has similar pattern to the electric field lines produced by an electric dipole. The main difference is that the magnetic field lines are closed loop (they have no origin and no ending point) while electric field lines always originate from positive charges and end on negative ch ...
Chapter 36 Summary – Magnetism
... 1. All magnets have a _________________ pole and ________________ pole that cannot be isolated. 2. Like poles _________________, unlike poles __________________. 3. Earth has magnetic poles. a. A compass needle is small bar magnet that can freely ___________________. b. A compass needle always point ...
... 1. All magnets have a _________________ pole and ________________ pole that cannot be isolated. 2. Like poles _________________, unlike poles __________________. 3. Earth has magnetic poles. a. A compass needle is small bar magnet that can freely ___________________. b. A compass needle always point ...
3 Simultaneous Magnetic and Electric Fields
... F = qE + qv x B =0 qE = qv x B v=E/B An entering particle of this speed will continue moving straight across the plates. If the particle has a different speed, then the magnetic force will be different and the net force will not be zero. ...
... F = qE + qv x B =0 qE = qv x B v=E/B An entering particle of this speed will continue moving straight across the plates. If the particle has a different speed, then the magnetic force will be different and the net force will not be zero. ...
Force between magnets
Magnets exert forces and torques on each other due to the complex rules of electromagnetism. The forces of attraction field of magnets are due to microscopic currents of electrically charged electrons orbiting nuclei and the intrinsic magnetism of fundamental particles (such as electrons) that make up the material. Both of these are modeled quite well as tiny loops of current called magnetic dipoles that produce their own magnetic field and are affected by external magnetic fields. The most elementary force between magnets, therefore, is the magnetic dipole–dipole interaction. If all of the magnetic dipoles that make up two magnets are known then the net force on both magnets can be determined by summing up all these interactions between the dipoles of the first magnet and that of the second.It is always more convenient to model the force between two magnets as being due to forces between magnetic poles having magnetic charges 'smeared' over them. Such a model fails to account for many important properties of magnetism such as the relationship between angular momentum and magnetic dipoles. Further, magnetic charge does not exist. This model works quite well, though, in predicting the forces between simple magnets where good models of how the 'magnetic charge' is distributed is available.