The Particle Nature of EM Radiation (Edexcel International A Level Physics)
Revision Note
The Particle Nature of EM Radiation
The Particle Nature of Light
In classical wave theory, electromagnetic (EM) radiation is assumed to behave as a wave
This is demonstrated by the fact EM radiation exhibits phenomena such as diffraction and interference
However, experiments from the last century, such as the photoelectric effect and atomic line spectra, can only be explained if EM radiation is assumed to behave as particles
Evidence for the Particle Nature of Light
The best evidence for the particle nature of light comes from the photoelectric effect
This is demonstrated using the Gold-leaf Electroscope
Observations of the Gold Leaf Experiment
The explanation for these observations supports the theory of light as a particle, specifically a discrete packet (or photon) of energy
Placing the UV light source closer to the metal plate causes the gold leaf to fall more quickly
Using a higher frequency light source does not change how quickly the gold leaf falls
Using a filament light source causes no change in the gold leaf’s position
Using a positively charged plate causes no change in the gold leaf’s position
Emission of photoelectrons happens as soon as the radiation is incident on the surface of the metal
Each of the observations is explained below
Typical set-up of the gold leaf electroscope experiment
Placing the UV light source closer to the metal plate causes the gold leaf to fall more quickly
Placing the UV source closer to the plate increases the intensity incident on the surface of the metal
Increasing the intensity, or brightness, of the incident radiation increases the number of photoelectrons emitted per second
Therefore, the gold leaf loses negative charge more rapidly
Using a higher frequency light source does not change how quickly the gold leaf falls
The maximum kinetic energy of the emitted electrons increases with the frequency of the incident radiation
In the case of the photoelectric effect, energy and frequency are independent of the intensity of the radiation
So, the intensity of the incident radiation affects how quickly the gold leaf falls, not the frequency
Using a filament light source causes no change in the gold leaf’s position
If the incident frequency is below a certain threshold frequency, no electrons are emitted, no matter the intensity of the radiation
A filament light source has a frequency below the threshold frequency of the metal, so, no photoelectrons are released
Using a positively charged plate causes no change in the gold leaf’s position
If the plate is positively charged, that means there is an excess of positive charge on the surface of the metal plate
Electrons are negatively charged, so they will not be emitted unless they are on the surface of the metal
Any electrons emitted will be attracted back by positive charges on the surface of the metal
Emission of photoelectrons happens as soon as the radiation is incident on the surface of the metal
A single photon interacts with a single electron
If the energy of the photon is equal to the work function of the metal, photoelectrons will be released instantaneously
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