1. Lecture 12: Waves versus particles
2. Corpuscular Theory of Light (1704) Isaac Newton proposed that light consists of a stream of small particles, because it�
travels in straight lines at great speeds
is reflected from mirrors in a predictable way
3. Wave Theory of Light (1802) Thomas Young showed that light is a wave, because it�
undergoes diffraction and interference �(Youngs double-slit experiment)
4. Particles Position x
Mass m
Momentum p = mv
5. Waves Wavelength l
Amplitude A
Frequency f
number of cycles per second �(Hertz)
6. Waves versus Particles A particle is localised in space, and has discrete �physical properties such as mass
A wave is inherently spread out over many wave-lengths in space, and could have amplitudes in a continuous range
Waves superpose and pass through each other, �while particles collide and bounce off each other
7. Diffraction
8. Interference
9. Interference Fringes on a Screen
10. Blackbody Radiation A blackbody is an object which totally absorbs all radiation that falls on it
Any hot body (blackbodies included) radiates light �over the whole spectrum of frequencies
The spectrum depends on both frequency and temperature
11. Spectrum of Blackbody Radiation
12. Ultraviolet Catastrophe
13. Plancks Quantum �Postulate (1900) A blackbody can only emit radiation in�discrete packets or quanta, i.e., in �multiples of the minimum energy:�� E = hf��where h is a constant and f is the �frequency of the radiation
14. Plancks Quantum Postulate (contd) Thus, it is harder for a blackbody to emit radiation at short wavelengths (high frequency) �
since higher energies are required to produce each quanta of radiation, by Plancks formula
This explains the origin of the ultraviolet catastrophe
15. Plancks Constant Experimentally determined to be�� h = 6.63 x 10-34 Joule sec��(Joule = kg m2 / sec2)
A new constant of nature, which turns out to be of fundamental importance in the new quantum theory
16. Photoelectric Effect
17. Photoelectric Effect (contd)
18. Experimental Observations Only light with a frequency greater than a certain threshold will produce a current
Current begins almost instantaneously, even for light �of very low intensity
Current is proportional to the intensity of the incident light
19. Problems with Wave Theory of Light The wave theory of light is unable to explain these observations
For waves, energy depends on amplitude and not frequency
This implies that a current should be produced when say, high-intensity red light is used
20. Einsteins Explanation �(1905) Light consists of particles, �now known as photons
A photon hitting the emitter �plate will eject an electron�if it has enough energy
Each photon has energy:�� E = hf��(same as Plancks formula)
21. Everyday Evidence for Photons Red light is used in photographic darkrooms because �it is not energetic enough to break the halogen-silver bond in black and white films
Ultraviolet light causes sunburn but visible light does not because UV photons are more energetic
Our eyes detect colour because photons of different energies trigger different chemical reactions in retina cells
22. Double-Slit Experiment�to illustrate wave nature of light
23. Double-Slit Experiment �with a machine gun!
24. Double-Slit Experiment �with electron gun
25. Interference Pattern of Electrons Determines the probability of an electron arriving at a�certain spot on the screen
After many electrons, �resembles the inter-�ference pattern of light
26. Double-Slit Experiment �with electron gun and detector
27. Summary Waves and particles exhibit very different behaviour
Yet, light sometimes behaves like particles
spectrum of blackbody radiation
photoelectric effect
And electrons sometimes behave like waves
interference pattern of electrons
In quantum theory, the distinction between waves �and particles is blurred
