Rayleigh–Jeans law: Difference between revisions

Comparison of Rayleigh–Jeans law with Wien approximation and Planck's law, for a body of 8 mK temperature.

In physics, the Rayleigh–Jeans Law, first proposed in the early 20th century, attempts to describe the spectral radiance of electromagnetic radiation at all wavelengths from a black body at a given temperature through classical arguments. For wavelength ${\displaystyle \lambda }$, it is;

${\displaystyle B_{\lambda }(T)={\frac {2ckT}{\lambda ^{4}}}}$

where c is the speed of light, k is Boltzmann's constant and T is the temperature in kelvins. For frequency ${\displaystyle \nu }$, it is;

${\displaystyle B_{\nu }(T)={\frac {2\nu ^{2}kT}{c^{2}}}}$.

The Rayleigh–Jeans expression agrees with experimental results at large wavelengths (or, equivalently, low frequencies) but strongly disagrees at short wavelengths (or high frequencies). This inconsistency is commonly known as the ultraviolet catastrophe.^{[1] [2]}

Historical development

In 1900, the British physicist Lord Rayleigh derived the ${\displaystyle \lambda ^{-4}}$ dependence of the Rayleigh–Jeans law based on classical physical arguments.^[3] A more complete derivation, which included the proportionality constant, was presented by Rayleigh and Sir James Jeans in 1905. The derived expression had two problems: It predicted an energy output that diverges towards infinity as wavelength approaches zero (as frequency tends to infinity) and measurements of energy output at short wavelengths disagreed with the result from the Rayleigh–Jeans expression.

Comparison to Plank's law

In 1900 Max Planck empirically derived an expression for Blackbody Radiation expressed in terms of wavelength λ = c /ν:

${\displaystyle B_{\lambda }(T)={\frac {2c^{2}}{\lambda ^{5}}}~{\frac {h}{e^{\frac {hc}{\lambda kT}}-1}}}$

where h is Planck's constant. The Planck law does not suffer from an ultraviolet catastrophe, and agrees well with the experimental data, but its full significance (which ultimately led to quantum theory) was only appreciated several years later. In the limit of very high temperatures or long wavelengths, the term in the exponential becomes small, and so the denominator becomes approximately hc /λkT by power series expansion. Specifically,

${\displaystyle {\frac {1}{e^{\frac {hc}{\lambda kT}}-1}}\approx {\frac {1}{\frac {hc}{\lambda kT}}}={\frac {\lambda kT}{hc}}}$

which results in the full Plank Function reducing to

${\displaystyle B_{\lambda }(T)={\frac {2ckT}{\lambda ^{4}}}}$

which is identical to the classically derived Rayleigh–Jeans expression.

The same argument can be applied to the Blackbody Radiation expressed in terms of frequency ${\displaystyle \nu ={\frac {c}{\lambda }}}$ in the limit of small frequency:

${\displaystyle B_{\nu }(T)={\frac {2h\nu ^{2}/c^{2}}{e^{\frac {h\nu }{kT}}-1}}\approx {\frac {2h\nu ^{3}}{c^{2}}}*{\frac {kT}{h\nu }}={\frac {2kT\nu ^{2}}{c^{2}}}}$

For both the frequency and wavelength dependent expressions, the Plank Function reduces to the Rayleigh–Jeans law in the limit of large wavelength or short frequency.

Consistency of frequency and wavelength dependent expressions

When comparing the frequency and wavelength dependent expressions of the Rayleigh–Jeans law it is important to remember that

${\displaystyle B_{\lambda }(T)\neq B_{\nu }(T)}$

because the Left-Hand-Side of the expression has units of energy emitted per unit time per unit area of emitting surface, per unit solid angle, per unit wavelength, whereas the Right-Hand-Side has units of energy emitted per unit time per unit area of emitting surface, per unit solid angle, per unit frequency. To be consistent, we must use the equality

${\displaystyle B_{\lambda }*d\lambda =B_{\nu }*d\nu }$

where both sides now have units of energy emitted per unit time per unit area of emitting surface, per unit solid angle.

Starting with the Rayleigh–Jeans law in terms of wavelength we get

${\displaystyle B_{\lambda }(T)=B_{\nu }(T)*{\frac {d\nu }{d\lambda }}}$

where

${\displaystyle {\frac {d\nu }{d\lambda }}={\frac {d}{d\lambda }}\left({\frac {c}{\lambda }}\right)=-{\frac {c}{\lambda ^{2}}}}$.

This leads us to find:

${\displaystyle B_{\lambda }(T)={\frac {2kT\left({\frac {c}{\lambda }}\right)^{2}}{c^{2}}}*{\frac {c}{\lambda ^{2}}}={\frac {2ckT}{\lambda ^{4}}}}$.

Other forms of Rayleigh–Jeans law

Depending on the application, the Plank Function can be expressed in 3 different forms. The first involves energy emitted per unit time per unit area of emitting surface, per unit solid angle, per unit frequency. In this form, the Plank Function and associated Rayleigh–Jeans limits are given by

${\displaystyle B_{\lambda }(T)={\frac {2c^{2}}{\lambda ^{5}}}~{\frac {h}{e^{\frac {hc}{\lambda kT}}-1}}\approx {\frac {2ckT}{\lambda ^{4}}}}$

or

${\displaystyle B_{\nu }(T)={\frac {2h\nu ^{2}/c^{2}}{e^{\frac {h\nu }{kT}}-1}}\approx {\frac {2kT\nu ^{2}}{c^{2}}}}$

Alternatively, Planck's law can be written as an expression ${\displaystyle u(\nu ,T)=\pi I(\nu ,T)}$ for emitted power integrated over all solid angles. In this form, the Plank Function and associated Rayleigh–Jeans limits are given by

${\displaystyle u(\lambda ,T)={\frac {2\pi c^{2}}{\lambda ^{5}}}~{\frac {h}{e^{\frac {hc}{\lambda ^{4}kT}}-1}}\approx {\frac {2\pi ckT}{\lambda ^{4}}}}$

or

${\displaystyle u(\nu ,T)={\frac {2\pi h\nu ^{2}/c^{2}}{e^{\frac {h\nu }{kT}}-1}}\approx {\frac {2\pi kT\nu ^{2}}{c^{2}}}}$

In other cases, Plank's Law is written as ${\displaystyle \rho (\nu ,T)={\frac {4\pi }{c}}I(\nu ,T)}$ for energy per unit volume (energy density). In this form, the Plank Function and associated Rayleigh–Jeans limits are given by

${\displaystyle \rho (\lambda ,T)={\frac {8\pi c}{\lambda ^{5}}}~{\frac {h}{e^{\frac {hc}{\lambda kT}}-1}}\approx {\frac {8\pi kT}{\lambda ^{4}}}}$

or

${\displaystyle \rho (\nu ,T)={\frac {8\pi h\nu ^{2}/c^{3}}{e^{\frac {h\nu }{kT}}-1}}\approx {\frac {8\pi kT\nu ^{2}}{c^{3}}}}$

See also

• John William Strutt, 3rd Baron Rayleigh
• Wien's displacement law
• Stefan–Boltzmann law

External links

• Rayleigh–Jeans Law and Schrodinger's Cat
• Derivation at HyperPhysics

References

1. Astronomy: A Physical Perspective, Mark L. Kutner pp. 15
2. Radiative Processes in Astrophysics, Rybicki and Lightman pp. 20-28
3. Astronomy: A Physical Perspective, Mark L. Kutner pp. 15