Radiation Transfer in Cloud Layers

Abstract

For 2n-stream radiation transfer theory, a stack of m clouds can be represented as an equivalent cloud. Individual clouds, indexed by c = 1, 2, 3, ..., m are characterized by 2n x 2n scattering matrices Sc, that describe how the cloud interacts with 2n streams of axially symmetric incoming radiation, propagating in upward and downward Gauss-Legendre sample directions. Some of the radiation is transmitted, some is absorbed and converted to heat and some is scattered into 2n outgoing streams along the directions of the incoming streams. The clouds are also characterized by 2n x 1 thermal source vectors |Jdotc that describe the thermal emission of radiation along the stream directions by cloud particulates and gas molecules. The 2n x 2n scattering matrix of the equivalent cloud, Sev = Sm*Sm-1 *...*S2*S1, is the Redheffer star product of the scattering matrices Sc of the individual clouds. The 2n x 1 thermal source vector for the equivalent cloud |Jdotev=G[m,m|Jdotm + G[m,m-1|Jdotm,m-1 + ... + G[m,1|Jdot1 is a linear combination of the thermal source vectors of the individual clouds. The 2n x 2n discrete Green's matrices G[m,c can be constructed from the scattering matrices Sc of individual clouds. The equivalent scattering matrix Sev and the equivalent thermal source vector |Jdotev are analogous to the equivalent resistance and the equivalent electromotive force of Thevenin's theorem for a network of electrical circuits. Illustrative numerical examples are given for single clouds, 3-cloud stacks and 10-cloud stacks. These methods are useful for modeling radiation transfer in Earth's atmosphere, which can be represented by layers of invisible clouds, consisting of clear air and greenhouse gases, or visible clouds which also include condensed water, smog, etc.

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