- 1 Enter The Following Simulator Http Www Sc Ehu Es Sbweb Fisica3 Cuantica Compton Compton Html 2 In The Indicated S 1 (100.09 KiB) Viewed 11 times
http://www.sc.ehu.es/sbweb/fisica3/cuan ... mpton.html
1) Enter the following simulator: http://www.sc.ehu.es/sbweb/fisica3/cuan ... mpton.html 2) In the indicated simulator, modify the angle of the detector position of the scattered photons, and proceed to fill in the following table: Detector angle [grados] 0 45 60 90 145 160 Explain the relative intensity graphs (of the radiations), what happens to the photons (incident and scattered), and to the scattered electron after impact. 3) For each of the angles considered in the previous section, calculate the frequency, energy and amount of motion of the incident and scattered photons; and the kinetic energy and amount of motion of the scattered electron. Proceed to fill in the following table: 0 45 60 90 145 160 0 45 60 Incident photon wavelength A Wavelength of the scattered [Angstroms] photon [Angstroms] 0,018780 0,018780 0,018780 0,018780 0,018780 0,018780 Angle Y E p V [degrees] [Hz] [ev] [kgm/seg] [Hz] Angulo d Incident photon E = hv p=hu/c 90 145 160 (a) A [m] Average Planck constant h [J*seg] E=mc² p=0 Target electron E [ev] Scattered photon /e Scattered electron p NOTE: Express energy in terms of electron volts (eV). 4) Using the equation of the Compton effect, determine the Planck constant for each of the cases in the table in point 1, and then the average Planck constant. Then compare to the universally accepted Planck constant. X' - λ = h moc A' [m] E=√m²c²+p²c² P=P E = hu' p= hv²/c [kgm/seg] (1 - cos ) Te [ev] pe [Kgm/seg] h [J* sec]