Using the four-vector formalism, obtain the angle dependence of the energy of the photons that are...

Compton used photons of wavelength equal yo 0.0711 nm a) whats is the energy of these...

Compton used photons of wavelength equal yo 0.0711 nm a) whats is the energy of these photons? b) whats is the wavelength of the scattered photons at an angle of 180°( back scatter case ). c) what is the energy of the electrons scattered backwards?

Electromagnetic radiation with 0.8 MeV of energy is scattered from stationary electrons. The scatterd photons have...

Electromagnetic radiation with 0.8 MeV of energy is scattered from stationary electrons. The scatterd photons have wavelength equal to Compton wavelength. Through what angle were the photons scattered?

Photons of energy 1.2 MeV impart on a carbon target. Under which angle are photons of...

Photons of energy 1.2 MeV impart on a carbon target. Under which angle are photons of wavelength 0.004 nm detected?

A neutron collides elastically with a helium nucleus (at rest initially) whose mass is four times...

A neutron collides elastically with a helium nucleus (at rest initially) whose mass is four times that of the neutron. The helium nucleus is observed to move off at an angle θ′2=45∘. The neutron's initial speed is 4.1×105 m/s Determine the speeds of the two particles, v′n and v′He, after the collision. Express your answers using two significant figures. Enter your answers numerically separated by a comma.

A neutron collides elastically with a helium nucleus (at rest initially) whose mass is four times...

A neutron collides elastically with a helium nucleus (at rest initially) whose mass is four times that of the neutron. The helium nucleus is observed to move off at an angle θ′2=45∘. The neutron's initial speed is 6.9×105 m/s. 1) Determine the angle of the neutron, θ′1, after the collision? θ′1= ??? 2) Determine the speeds of the two particles, v′n and v′He′, after the collision. v′n , v′He′ = ???

A neutron collides elastically with a helium nucleus (at rest initially) whose mass is four times...

A neutron collides elastically with a helium nucleus (at rest initially) whose mass is four times that of the neutron. The helium nucleus is observed to rebound at an angle '2 = 42° from the neutron's initial direction. The neutron's initial speed is 6.8 105 m/s. a. Determine the angle at which the neutron rebounds, '1, measured from its initial direction. (in degrees) b. What is the speed of the neutron after the collision? c. What is the speed of...

X-rays of unknown energy are scattered off a carbon target. At a scattering angle of 70...

X-rays of unknown energy are scattered off a carbon target. At a scattering angle of 70 degrees, the radiation quanta are found to have an energy of 350 keV. What is the energy of the incoming radiation quanta

a) Protons with 1.0 MeV energy are scattered from the golden nucleus at an angle of...

a) Protons with 1.0 MeV energy are scattered from the golden nucleus at an angle of 450. What is the shortest distance that protons can approach the nucleus? b) An object is launched from the earth's surface to the Moon at a speed of 15,000 m / s. What is the velocity of this object when it reaches the surface of the Moon? Neglect the friction of the earth's atmosphere. Accept that the Earth and the Moon are immobile. c)...

The first four energy level in arbitrary units of energy of an unknown element are listed...

The first four energy level in arbitrary units of energy of an unknown element are listed below: n 1 2 3 4 ... infinity E -20 -9 -4 -3 ... 0 A gaseous sample of the element is bombarded by photons with energies in these units of 20, 16, 15, 11, 9, and 1. Which of these photons could potentially be absorbed by an electron in the n=1 state of the element? In each case, indicate the transition that would...

In a photoelectric experiment using a clean metal surface, the maximum energy of the emitted photons...

In a photoelectric experiment using a clean metal surface, the maximum energy of the emitted photons was measured for a number of different incident frequencies, with the following results. Frequency (1014 Hz) Energy (eV) 11.8 2.61 10.6 2.17 9.9 1.89 9.1 1.48 8.2 1.07 6.9 0.48 Plot the graph of these results and find each of the following. (a) Planck's constant (b) the cutoff frequency (Hz) (c) the work function (eV)