2. De-Brogile
Hypothesis:
Hypothesis:
“De Broglie's hypothesis of matter waves postulates that the electrons any particle
of matter that has linear momentum is also a wave. The wavelength of a matter
wave associated with a particle is inversely proportional to the magnitude of the
particle's linear momentum. The speed of the matter wave is the speed of the
particle”
3. Introduction:
• This Hypothesis was Proposed
by Luios De-Brogile in 1924.
• This hypothesis forms the basis of the
de-Brogile theory of wave particle
duality.
4. Why was it important to propose
and formulate this hypotheis?
• Upon the confirmation of wave nature of light experimentally as well as particle nature
of light radiation. It was neccesary to define the characteristic of light radation as a
particle as well as wave.
• De-brogile combines the wave energy equation 𝜀 = ℎ𝑣 and energy equation
representing particle i.e. 𝑒 = 𝑚𝑐2 and gave a combine equation that represents the
both wave and particle nature of light.
5. Derivation:
mc2 =hv
In this equation (m) is the momentum that can be represented by P. So the same equation
can be written as;
Pc = hv
since the velocity of the light is represented by “C” so C = V𝝀 .
Substituting the value of c we get:
Pc = hv
Pv𝝀 = hv
P𝝀 = h
P =
𝒉
𝝀
This is final equation of Debrogile Hypothesis
6. • In 1927, physicists Clinton Davisson and Lester Germer, of Bell Labs, performed an experiment where they
fired electrons at a crystalline nickel target. The resulting diffraction pattern matched the predictions of the
de Broglie wavelength. De Broglie received the 1929 Nobel Prize for his theory (the first time it was ever
awarded for a Ph.D. thesis) and Davisson/Germer jointly won it in 1937 for the experimental discovery of
electron diffraction (and thus the proving of de Broglie's hypothesis)
• Further experiments have held de Broglie's hypothesis to be true, including the quantum variants of the
double slit experiment. Diffraction experiments in 1999 confirmed the de Broglie wavelength for the
behavior of molecules as large as buckyballs, which are complex molecules made up of 60 or more carbon
atoms.
Experimental proof:
7. Significance of this Hypotheis:
The de Broglie hypothesis showed that wave-
particle duality was not merely an aberrant
behavior of light, but rather was a
fundamental principle exhibited by both
radiation and matter. As such, it becomes
possible to use wave equations to describe
material behavior, so long as one properly
applies the de Broglie wavelength. This
would prove crucial to the development of
quantum mechanics. It is now an integral
part of the theory of atomic structure and
particle physics.