Difference between revisions of "Radius of Curvature Calculation"
Jump to navigation
Jump to search
| Line 10: | Line 10: | ||
<math>r = \frac{\rho}{q*B}</math> | <math>r = \frac{\rho}{q*B}</math> | ||
| + | |||
| + | To get the momentum of the incident electrons where momentum is <math>\frac{kg*m}{s}</math> the energy of the beam which | ||
For this sample equation 1 MeV will be used to determine the radius of curvature per MeV of the incident beam. | For this sample equation 1 MeV will be used to determine the radius of curvature per MeV of the incident beam. | ||
| − | Energy = 1 MeV | + | Energy = 1 MeV = <math> 1 * 10^6 \frac{J}{C} * 1.6022 * 10^{-19}C = 1*10^6\frac{kg * m^2}{s^2 * C} * 1.6022 * 10^{-19}C </math> |
Magnetic Field (B) = 0.35 Tesla | Magnetic Field (B) = 0.35 Tesla | ||
| − | Charge of an electron = <math>1.6022 * 10^{19} | + | Charge of an electron = <math>1.6022 * 10^{19} Coulombs</math> |
Revision as of 08:37, 17 February 2009
Below are my calculations done for determining the radius of curvature of an electron/positron in the magnetic field for the pair spectrometer.
The Lorentz force is the centripetal force acting upon the electron/positron in the magnetic field which gives the following equation.
This equation can be rearranged to solve for r (and given that mv = momentum) to give the following equation
To get the momentum of the incident electrons where momentum is the energy of the beam which
For this sample equation 1 MeV will be used to determine the radius of curvature per MeV of the incident beam.
Energy = 1 MeV =
Magnetic Field (B) = 0.35 Tesla
Charge of an electron =