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Interaction Between Ionizing Radiation And Matter, Problems Photons Audun Sanderud

Department of Physics University of Oslo. Interaction Between Ionizing Radiation And Matter, Problems Photons Audun Sanderud. Problem 7.1.

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Interaction Between Ionizing Radiation And Matter, Problems Photons Audun Sanderud

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  1. Department of PhysicsUniversity of Oslo Interaction Between Ionizing Radiation And Matter, Problems PhotonsAudun Sanderud

  2. Problem 7.1 • Is the mass Compton attenuation/energy transfer coefficient larger in carbon or lead?Solution: ←Independent of ZCarbon: NAZ/A=0.49954NALead: NAZ/A=0.39575NANA=6.0022 1023

  3. Problem 7.2 • Why is Rayleigh scattering not plotted in Fig. 7.16a,b, although quite significant in Fig. 7.13a,b?Solution:

  4. Problem 7.3 • On the basis of the K-N theory, what is the ratio of the Compton interaction cross section per atom for lead and carbon?Solution:

  5. Problem 7.4 • Calculate the energy of the Compton-scattered photon at q= 0, 45 , 90  and 180 for hn = 50 keV, 500 keV and 5 MeV.Solution: hn´:

  6. Problem 7.5 • What are the corresponding energies and angels of the recoiling electrons for the cases in problem 4?Solution: T: j:

  7. Problem 7.6 • Calculate for 1-MeV photons the total K-N cross section from Eq.(7.15), and derive the Compton mass attenuation coefficient for copper in cm2/g and m2/kg.Solution:

  8. Problem 7.7 • What is the maximum energy, what is the average energy, of the Compton recoil electrons generated by 20-keV and 20-MeV g-rays?Solution:

  9. Problem 7.8 • Calculate the energy of a photoelectron ejected from the K-shell in tin by a 40-keV photon. Calculate ttr/r; you may estimate from fig. 7.15.Solution: Tin: K-edge 29.20keV T=hv-Tb=(40-29.20)keV=10.80keV

  10. Problem 7.9 • What is the average energy of the charged particles resulting from pair production in (a) the nuclear field (b) the electron field, for photons of hn = 2 and 20 MeV?Solution: a) b)

  11. Problem 7.10 • A narrow beam containing 1020 photons at 6 MeV impinges perpendicularly on a layer of lead 12 mm thick, having a density 11.3 g/cm3. How many interactions of each type (photoelectric, Compton, pair, Rayleigh) occur in the lead?Solution: Number of interactions ∆Ntot =N0(1-e-∆x µ)∆N´tot =N0∆x µ = N0∆x(tp.el+sC+kpair +sR) =∆N´p.el+∆N´C+∆N´pair+∆N´R >∆Ntot∆Np.el =∆N´p.el·∆Ntot/ ∆N´tot

  12. Problem 7.10 • A narrow beam containing 1020 photons at 6 MeV impinges perpendicularly on a layer of lead 12 mm thick, having a density 11.3 g/cm3. How many interactions of each type (photoelectric, Compton, pair, Rayleigh) occur in the lead?Solution: Number of interactions ∆Ntot =N0(1-e-∆x µ)∆N´tot =N0∆x µ = N0∆x(tp.el+sC+kpair +sR) =∆N´p.el+∆N´C+∆N´pair+∆N´R >∆Ntot∆Np.el =∆N´p.el·∆Ntot/ ∆N´tot

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