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Quantization of Light It seemed to be a wave....

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Presentation on theme: "Quantization of Light It seemed to be a wave...."— Presentation transcript:

1 Quantization of Light It seemed to be a wave...

2 Black-body Radiation Does not preferentially absorb or emit any particular frequency Light in thermal equilibrium with surroundings Experimentally realized as “Cavity” radiation

3 Black-Body Spectrum Classically, emission at short wavelengths would be infinite Planck correctly modeled spectrum by assuming E = hf Sharp drop in high-f “photons”

4 Photoelectric Effect Light absorbed by a metal can eject electrons
Energy of photoelectrons did not depend on light intensity P/A (Instead, that determined the current) Light frequency determined photoelectron energy

5 Photoelectric Effect Explained by Einstein E = hf – f
slope = h E f –f Verified by Millikan

6 Photoelectric Effect Work function f of metal
property of the metal potential energy of bound electron light carries and delivers energy in hf packets (photons) Light can act as discrete particles, not just continuous waves

7 X rays “Braking radiation” from stopped electrons
Electromagnetic radiation X – + V hfmax = Ke = Ve

8 X rays are Light Uncharged Diffract from crystals

9 Compton Effect X-rays lose energy scattering from electrons
hf1 hf2 X-rays lose energy scattering from electrons Interpreted as elastic scattering conserving momentum

10 Photon Momentum E2 = (mc2)2 + (pc)2 (hf)2 = (pc)2 hf = pc p = hf/c p = h(c/l)/c p = h/l

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