An electron initially at rest recoils after a head-on collision with a 5.05-keV photon. Determine the...

An electron initially at rest recoils after a head-on collision with a 8.27-keV photon. Determine the...

An electron initially at rest recoils after a head-on collision with a 8.27-keV photon. Determine the kinetic energy acquired by the electron.

In the Compton effect, a 0.133 nm photon strikes a free electron in a head-on collision...

In the Compton effect, a 0.133 nm photon strikes a free electron in a head-on collision and knocks it into the forward direction. The rebounding photon recoils directly backward. Use conservation of (relativistic) energy and momentum to determine the kinetic energy of the electron. Use the equation p=E/c=hf/c=h/λ. K =    eV Determine the wavelength of the recoiling photon. λ′ =    nm

In the Compton effect, a 0.128 nm photon strikes a free electron in a head-on collision...

In the Compton effect, a 0.128 nm photon strikes a free electron in a head-on collision and knocks it into the forward direction. The rebounding photon recoils directly backward. Part A Use conservation of (relativistic) energy and momentum to determine the kinetic energy of the electron. Use the equation p=Ec=hfc=h?. K = eV Part B Part complete Determine the wavelength of the recoiling photon. ?? = 0.133 nm

A 0.475 nm photon collides with a stationary electron. After the collision, the electron moves forward...

A 0.475 nm photon collides with a stationary electron. After the collision, the electron moves forward and the photon recoils backward. Find the momentum and the kinetic energy of the electron.

A 0.343-nm photon collides with a stationary electron. After the collision, the electron moves forward and...

A 0.343-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. kg · m/s (b) Find the kinetic energy of the electron. eV

One electron collides elastically with a second electron initially at rest. After the collision, the radii...

One electron collides elastically with a second electron initially at rest. After the collision, the radii of their trajectories are 1.00 cm and 2.60 cm. The trajectories are perpendicular to a uniform magnetic field of magnitude 0.0560 T. Determine the energy (in keV) of the incident electron.

One electron collides elastically with a second electron initially at rest. After the collision, the radii...

One electron collides elastically with a second electron initially at rest. After the collision, the radii of their trajectories are 1.50 cm and 3.20 cm. The trajectories are perpendicular to a uniform magnetic field of magnitude 0.0380 T. Determine the energy (in keV) of the incident electron.

A photon with wavelength of 0.1110 nm collides with a free electron that is initially at...

A photon with wavelength of 0.1110 nm collides with a free electron that is initially at rest. After the collision the wavelength is 0.1135 nm . Part A What is the kinetic energy of the electron after the collision? K = ??? J Part B What is its speed? v = ??? m/s Part C If the electron is suddenly stopped (for example, in a solid target), all of its kinetic energy is used to create a photon. What is...

An X-Ray photon with an energy of E = 128 keV undergoes Compton Scattering at an...

An X-Ray photon with an energy of E = 128 keV undergoes Compton Scattering at an angle of θ = 33°. What is the wavelength (λ0) of the incident photon (in nm)? Use h = 4.136 x 10-15 eVs and c = 3 x 108 m/s. What is the wavelength (λ') of the scattered photon (in nm)? What is the energy (E’) if the scattered photon (in keV)? Use h = 4.136 x 10-15 eVs and c = 3 x...

In a head-on collision of an electron of kinetic energy of 2.044 MeV with a positron...

In a head-on collision of an electron of kinetic energy of 2.044 MeV with a positron at rest, the two particles are replaced by two photons of equal energy. If each photon is traveling at an angles θ with respect to the electron’s direction of motion, What is the energy E, momentum p (you can leave the answer in terms of c) and angle of θ of each photon? (For electron and positron mc2 = 0.511 MeV)