Energy Quanta
One experiment that demonstrates an inconsistency between experimental results and the classical theory of light is called the photoelectric effect. If monochromatic light is incident on a clean surface of a material, then under certain conditions, electrons (photo electrons) are emitted from the surface. According to classical physics. if the intensity of the light is large enough, the work function of the material will be overcome and an electron will be emitted from the surface independent of the incident frequency. This result is not observed. The observed effect is that, at a constant incident intensity, the maximum kinetic energy of the photo electron varies linearly with frequency with a limiting frequency v = Vo. below which no photo electron is produced. This result is shown in Figure 2.1. If the incident intensity varies at a constant frequency, the rate of photo electron emission changes, but the maximum kinetic energy remains the same. Planck postulated in I900 that thermal radiation is emitted from a heated surface in discrete packets of energy called qunnta. The energy of these quanta is given by E = hv, where v is the frequency of the radiation and h is a constant now known as Planck's constant (h=6.63x10-34J-s)
Then in 1905. Einstein interpreted
the photoelectric results by suggesting that the energy in a light wave is also
contained in discrete packets or bundles. The particle-like packet of energy is
called aphoton, whose energy is also given by E = hv. A photon with sufficient
energy, then, can knock an electron from the sul-face of the material. The minimum
energy required to remove an electron is called the work function of the material
and any excess photon energy goes into the kinetic energy of the photoelectron.
This result was confirmed experimentally as demonsttated in Figure 2.1. The photoelectric
effect shows the discrete nature of the photon and demonstrates the
particle-like behavior of the photon.
The maximum kinetic energy of the photoelectron can be written as
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Then in 1905. Einstein interpreted
the photoelectric results by suggesting that the energy in a light wave is also
contained in discrete packets or bundles. The particle-like packet of energy is
called aphoton, whose energy is also given by E = hv. A photon with sufficient
energy, then, can knock an electron from the sul-face of the material. The minimum
energy required to remove an electron is called the work function of the material
and any excess photon energy goes into the kinetic energy of the photoelectron.
This result was confirmed experimentally as demonsttated in Figure 2.1. The photoelectric
effect shows the discrete nature of the photon and demonstrates the
particle-like behavior of the photon.
The maximum kinetic energy of the photoelectron can be written as
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