In Figure 4-13, consider a point
P located on a surface that has an emissivity
ε, diffuse reflectivity
ρd, specular reflectivity
ρs, absorptivity
α, refractive index
n, and temperature
T. The body is assumed opaque, which means that no radiation is transmitted through the body. This is true for most solid bodies.
The total incoming radiative flux at P is called
irradiation and denoted
G. The total diffuse outgoing radiative flux at
P is called
radiosity and denoted
J. This radiosity is the sum of diffusively reflected and emitted radiation:
According to the Stefan-Boltzmann law, eb(T) is the power radiated across all wavelengths and depends on the forth power of the temperature:
The net inward radiative heat flux, q, is then given by the difference between the irradiation and the outgoing radiation (radiosity and specular reflected radiation):
Using Equation 4-90 and
Equation 4-91,
J can be eliminated and a general expression is obtained for the net inward heat flux into the opaque body based on
G and
T.