A 0.080 nm photon collides with a stationary electron. After the collision, the electron moves forward...
A 0.850-nm photon collides with a stationary electron. After the collision, the electron moves forward and the photon recoils backwards. (a) Find the momentum of the electron. is within 10% of the correct value. This may be due to roundoff error, or you could have a mistake in your calculation. Carry out all intermediate results to at least four-digit accuracy to minimize roundoff error. kg middot m/s (b) Find the kinetic energy of the electron. eV
3) A photon of energy 820 keV collides with an electron at rest. The photon eflects at an angle of 5o degrees. (a) Calculate the energy of the deflected photon. (b Calculate the kinetic energy of the electron after the collision. () Calculate the magnitude and direction of the electron momentum after the collision. (d) Calulate the wavelengths of the photon and electron after the collision.
An X-ray photon of wavelength 0.5 nm collides with a stationary free electron and scattered at 180° angle. If the Compton wavelength has the value rc=2.4x10-'nm, then: (a) find the wavelength and the Compton Shift of the scattered photon, (6 marks) (b) find the energy of the incident and scattered photon (in joule). (4 marks)
A photon with wavelength λ = 0.4g9 nm undergoes a one-dimensional collision with an initially stationary electrDn. Determine the following. (a) the momentum (in kev/c) of the electron (Enter the magnitude) h App y conservation o moment + pe Remember to apply the equation for the Compton shift in order to calculate the change in wavelength. What is the scattering angle for a head-on collision? ke c + p = = (b) the kinetic energy (in ev) of the electron...
A photon moving in the +x-direction, scatters off a free stationary electron. The wavelength of the incident photon is 0.0410 nm. After the collision, the electron moves at an angle α below the +x-axis, while the photon moves at an angle θ = 73.3° above the +x-axis. (For the purpose of this exercise, assume that the electron is traveling slow enough that the non-relativistic relationship between momentum and velocity can be used.) (a) What is the angle α (in degrees)?...
6. Suppose that a 3.64 nm photon moving in the +x direction collides head-on with a 2 x 105 m/s electron moving in the -x direction. If the collision is perfectly elastic, find the conditions after collision. 6. Suppose that a 3.64 nm photon moving in the +x direction collides head-on with a 2 x 105 m/s electron moving in the -x direction. If the collision is perfectly elastic, find the conditions after collision.
6. Suppose that a 3.64 nm photon moving in the +x direction collides head-on with a 2 x 105 m/s electron moving in the -x direction. If the collision is perfectly elastic, find the conditions after collision.
Quantum Physics - Photon Momentum - Photon Scattering - Compton Effect 2 Photon Scattering by Electron - Compton Effect E = h' Ehf h (photon's momentum) 2 Before KW 2 After h 2-1=(1-cos) (Compton effect) m. = 2.43x10- Before After KEE E is between 0° and 180° The Planck constant is 6.626x10^-34 J s. The wavelength of the incident X-ray photon is unknown. The incident photon collides with the stationary electron. After the collision, the scattered photon's motion makes an...
A photon of wavelength 0.52500 nm strikes a free electron that is initially at rest. The photon is scattered straight backward. What is the speed of the recoil electron after the collision?
A photon of wavelength 0.30428 nm strikes a free electron that is initially at rest. The photon is scattered straight backward. What is the speed of the recoil electron after the collision?