A high frequency photon is scattered off of an electron and experiences a change of wavelength of 1.3 x 10^-4 nm. At what angle must a detector be placed to detect the scattered photon (relative to the direction of the incoming photon)? Answer to two significant figures.
A high frequency photon is scattered off of an electron and experiences a change of wavelength...
A photon of wavelength 0.04400 nm strikes a free
electron and is scattered at an angle of 36.0 ∘ from its original
direction.
Find the change in energy of the photon. ΑΣ eV Find the energy gained by the electron. eV
Find the change in energy of the photon. ΑΣ eV
Find the energy gained by the electron. eV
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)
An X-ray photon scatters from a free electron at rest at an angle of 105 relative to the incident direction Part A If the scattered photon has a wavelength of 0.340 nm, what is the wavelength of the incident photon? Express your answer using three significant figures. IVO ACO ? = nm Submit Request Answer Part B Determine the energy of the incident photon. Express your answer using three significant figures. ΤΡΙ ΑΣΦ ? EN keV Submit Request Answer Part...
In the Compton effect an X-ray photon scatters from a free electron. In such an experiment, an X-ray photon of wavelength 0.141 nm scatters at an angle of 135® from the incident direction. what is the momentum of the incident photon? Give your answer to at least three significant figures. Your answer must be accurate to 1%, 4.699340x104 kg m/s Previous Tries no.isisseaneenoonties Your receipt no. is 155-2231 What is the energy of the incident photon? Give your answer to...
7. An x-ray photon with wavelength of 1.92 pm scatters off of an electron at rest, deflecting through an angle of 120°. What's the scattered photon's frequency?
PC8.Q1 014] A photon with wavelength 0.120 nm scatters off an electron that is initially at rest. The speed of the recoiling, non-relativistic electron is 7.00x106 m/s immediately after the collision. a) Name this process and explain its significance for the b) Calculate the energy of the incoming photon and the c) Based on energy conservation calculate the energy of development of modern physics. [1] momentum of the recoiling electron. [2] the outgoing (scattered) photon and its wavelength. [31
In Compton scattering a photon collides with an electron that is initially at rest. (a) Rank the following quantities in order from largest to smallest. If any two quantities are the same, state this. Explain how you made your ranking. (i) The wavelength of an x-ray photon (ii) The change in wavelength of an x-ray photon in Compton scattering when it scatters through an angle of 0° (that is, the photon continues in the same direction as its initial motion)...
An x-ray photon is scattered from a free electron (mass m) at rest. The wavelength of the scattered photon is λ′, and the final speed of the struck electron is v. Part A Part complete What was the initial wavelength λ of the photon? Express your answer in terms of λ′, v, m, and the appropriate constants. For the wavelength of the scattered photon λ′ use the notation λf. (Hint: Use the relativistic expression for the electron kinetic energy.) Express...
2. We scatter x-rays (with wavelength 2) off of electrons and measure the final wavelength when they scatter to an angle of θ from the original direction. When 0 90, the observed final wavelength is A' 1.083 x 10-11 m. a. What's the incoming wavelength λ ? b. At what angle would we observe a scattered wavelength of A'- 1.204 x 10-11 m? What's the frequency of the incoming x-rays? What's the energy of such a photon in eV? c....
Q4D.1 (Requires completion of chapter R9.) If we shine X-rays (which are very high-frequency electromagnetic waves) at a target, both the wave and photon models of electromagnetic radiation predict that the X-rays will be scattered in all directions by the target. The wave model predicts that the scattered X-rays will have the same wave- length as that of the incoming X-rays (since the incoming waves will wiggle the electron at the same frequency, so the scattered waves emitted by the...