Measures of Dispersion and Variability: Range, QD, AD and SD
Photoelectric effect ppt
1. Light – Wave or Particle
Evidence Supporting Wave Nature of Light
• Reflection
• Refraction
• Diffraction
• Interference
Where did we observe these phenomena?
• Polarization
Where did we observe this phenomena?
2. Light – Wave or Particle
Evidence Supporting Particle Nature of
Light
Physics had yet to explain the following as of 1900:
•Atomic Spectra
Characteristic Color Pattern
• Blackbody Radiation
Absorption and Emission of Energy
• Photoelectric Effect
Photoemission of Electrons
4. Blackbody Radiation
A blackbody is an object/system that absorbs
all radiation in which it comes in contact.
Blackbody Radiation is the radiation emitted
from a blackbody based only on temperature.
(usually associated with stars, we can measure
temperature but not radiation levels)
7. Photoelectric Effect
Classical Physics vs. Quantum Mechanics
Classical
Quantum Mechanics
Physics (light as a
(light as a particle)
wave)
Whether electrons are The intensity of the The frequency of the
ejected depends on… light. light.
The kinetic energy of
The intensity of the The frequency of the
ejected electrons
light. light.
depends on
At low intensities, Occurs almost
Takes time. instantaneously above
electron ejection … a certain frequency.
Proves duality of light.
8. Photoelectric Effect
Classical vs. Quantum Mechanics
• These observations support light being a
particle rather than a wave.
• It requires that electromagnetic energy be
quantized as Max Planck proposed earlier in
his explanation of blackbody radiation.
• Albert Einstein extended Planck’s quantized
energy to a stream of photons.
9. Work Function
Definition
The minimum amount of energy required for an
electron to escape from a metal.
The value of the work function depends ONLY
on the metal.
10. Work Function
Threshold Frequency
The frequency of incident radiation (photons)
below which there is no ejection of electrons
from a metal.
Symbol – ft
Units – Hz
11. Photoelectric Effect Explained:
Light is going to hit the metal.
If the frequency of the light is above the
threshold frequency, then the loosely bound
electrons will be emitted (released from the metal).
Metals with more loosely bound electrons
will have a lower Threshold frequency,
so it will require less energy to release the
Electrons.