(a) Explain the effect of change in number and speed of incident electron on property of...

When an x-ray photon collides with an electron at rest,... Explain. A) the electron turns into...

When an x-ray photon collides with an electron at rest,... Explain. A) the electron turns into a photon. B) the electron absorbs the photon and becomes a proton. C) the energy of the x-ray photon is completely absorbed by the electron, which now has extra energy and momentum. D) the magnitude of the scattered photon's momentum is the same as that of the incident x-ray photon, but the direction of the momentum is altered. E) the frequency of the scattered...

An incident x-ray photon is scattered from a free electron that is initially at rest. The...

An incident x-ray photon is scattered from a free electron that is initially at rest. The photon is scattered straight back at an angle of 180? from its initial direction. The wavelength of the scattered photon is 8.80×10?2 nm . (A) What is the wavelength of the incident photon? (B) What is the magnitude of the momentum of the electron after the collision?

Derive an expression for the interaction between a photon incident on a nearly-free electron in an...

Derive an expression for the interaction between a photon incident on a nearly-free electron in an aluminum target. Make sure to consider conservation of both relativistic energy and momentum for the photon and electron before and after the interaction. If an incident photon has an energy of 662 keV, calculate the energy of the photon that is scattered through an angle of 35˚.

In the mercury atom, an electron is in the Ec energy level. Two photons are incident...

In the mercury atom, an electron is in the Ec energy level. Two photons are incident upon the electron. Photon 1 has a frequency of 5.28E14 Hz, and Photon 2 has a frequency of 4.37E14 Hz. a. Calculate which photon will be absorbed, and calculate the new energy level of the electron. Photon # (blank) will be absorbed. The new energy level is (blank). b. Calculate all the possible photon frequencies that the electron can emit to get back down...

A(n) x-ray photon has a wavelength of 7.80 ✕ 10−9 cm. Find the momentum, the frequency,...

A(n) x-ray photon has a wavelength of 7.80 ✕ 10−9 cm. Find the momentum, the frequency, and the energy of the photon in electron volts. (a) the momentum kg · m/s (b) the frequency Hz (c) the energy of the photon in electron volts eV Im having trouble. please help

Find the wavelength (in nm) of a photon whose energy is 6.70 × 10-19 J. The...

Find the wavelength (in nm) of a photon whose energy is 6.70 × 10-19 J. The maximum wavelength that an electromagnetic wave can have and still eject electrons from a metal surface is 507 nm. What is the work function W0 of this metal? Express your answer in electron volts. In the Compton effect, an X-ray photon of wavelength 0.16 nm is incident on a stationary electron. Upon collision with the electron, the scattered X-ray photon continues to travel in...

An X-ray photon is scattered at an angle of θ=180.0° from an electron that is initially...

An X-ray photon is scattered at an angle of θ=180.0° from an electron that is initially at rest. After scattering, the electron has a speed of 4.67 × 10^6 m/s. Find the wavelength of the incident X-ray photon.

A photon is incident on a hydrogen atom. The photon moves the electron from an n...

A photon is incident on a hydrogen atom. The photon moves the electron from an n = 5 energy level to an n = 10 energy level. A: Is this an absorption or emission process? Choose one. B: What is the wavelength, in nanometers, of the incident photon?

A photon incident on a stationary electron is scattered through an angle Φ. hf′ =hf-Eel X-ray...

A photon incident on a stationary electron is scattered through an angle Φ. hf′ =hf-Eel X-ray spectrum Total internal reflection The photoelectric effect Compton's work particle nature of light

In photoelectric effect, light photon is allowed to fall on a metal surface and a photoelectron...

In photoelectric effect, light photon is allowed to fall on a metal surface and a photoelectron is ejected with kinetic energy 2.6 eV. If the threshold frequency f0 = 2 x 10^14 Hz then calculate the frequency and energy of incident photon.