Black-body radiation: Difference between revisions

Planck's blackbody equation describes the spectral exitance of an ideal blackbody.

${\displaystyle M(\lambda ,T)[{\frac {W}{m^{2}m}}]={\frac {2\pi hc^{2}}{\lambda ^{5}(\exp ^{\frac {hc}{\lambda KT}}-1)}}}$

where:

Symbol	Units	Description
${\displaystyle \lambda }$	${\displaystyle [m]}$	Input wavelength
${\displaystyle T}$	${\displaystyle [K]}$	Input temperature
${\displaystyle h=6.6261\times 10^{-34}}$	${\displaystyle [J*s]}$	Planck's constant
${\displaystyle c=2.9979\times 10^{8}}$	${\displaystyle [{\frac {m}{sec}}]}$	Speed of light in vacuum
${\displaystyle k=1.3807\times 10^{-23}}$	${\displaystyle [erg*K]}$	Boltzmann constant

Note that the input ${\displaystyle \lambda }$ is in meters and that the output is a spectral irradiance in ${\displaystyle [W/m^{2}*m]}$. Omitting the ${\displaystyle \pi }$ term from the numerator gives the blackbody emission in terms of radiance, with units ${\displaystyle [W/m^{2}*sr*m]}$ where "sr" is steradians.

Taking the first derivative leads to the wavelength with maximum exitance. This is known as the Wien Displacement Law.

A closed form solution exists for the integral of the Planck blackbody equation over the entire spectrum. This is the Stefan-Boltzmann equation. In general, there is no known closed-form solution for the definite integral of the Planck blackbody equation; numerical integration techniques must be used.

The relationship between the ideal blackbody exitance and the actual exitance of a surface is given by emissivity.

An object at 300K (~30 Celsius) has a peak emission 9.66 microns. It has virtually no self-emission before 2.50 microns, hence self-emission is typically associated with the "thermal" regions of the EM spectrum. However, the Sun has a peak emission around 0.49 microns which is in the visible region of spectrum.