Physical Chemistry Third Edition

(C. Jardin) #1
642 14 Classical Mechanics and the Old Quantum Theory

T 25 2500 K

T 15 2000 K

0 1000 2000 3000
Infrared
region

T 35 3000 K

Rayleigh–Jeans
theory for
3000 K

Ultraviolet
region

Visible
region
λ/nm

Spectral radiant emittance

Figure 14.10 The Quantized Energies of an Oscillator as Postulated by Planck.The
horizontal line segments are plotted at the heights of the assumed energy values, 0,hν,
3 hν,4hν,5hν,6hν,7hν, etc.

walls, so that a conducting box can contain standing electromagnetic waves with nodes
at the walls. For a rectangular box, Rayleigh and Jeans counted the possible standing
waves of various wavelengths that could exist with nodes at the walls and computed
the average energy of each standing wave as a function of temperature using standard
methods of classical physics. Their result was

η(λ)dλ

2 πckBT
λ^4

dλ (14.4-2)

wherecis the speed of light,Tis the absolute temperature, andkBis Boltzmann’s
constant:

kB

R

NAv

 1. 38066 × 10 −^23 JK−^1

whereRis the ideal gas constant andNAvis Avogadro’s constant.
John William Strutt, 3rd Baron Rayleigh,
1842–1919, was the 1904 Nobel Prize
winner in physics, and Sir James Jeans,
1877–1946, was a British astronomer
and physicist.


Although the formula of Rayleigh and Jeans agrees with experiment for large values
of the wavelength, it predicts that the spectral radiant emittance becomes large without
bound in the limit of short wavelength, which contradicts experimental results. This
result is due to the fact that more and more standing waves can fit into a box if the
wavelength is made shorter and shorter. The failure of the Rayleigh–Jeans theory to
agree with experiment was called the “ultraviolet catastrophe.”
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