Abstract
A new multiple-scattering Monte Carlo 3-D radiative transfer model named McSCIA
(Monte Carlo for SCIAmachy) is presented. The backward technique is used to efficiently
simulate narrow field of view instruments. The McSCIA algorithm has been
formulated as a function of the Earth’s radius, and can thus perform simulations for
both plane-parallel and spherical atmospheres. The latter geometry is essential for the
interpretation of limb satellite measurements, as performed by SCIAMACHY on board
of ESA’s Envisat. The model can simulate UV-vis-NIR radiation.
First the ray-tracing algorithm is presented in detail, and then successfully validated
against literature references, both in plane-parallel and in spherical geometry. A simple
1-D model is used to explain two different ways of treating absorption. One method
uses the single scattering albedo while the other uses the equivalence theorem. The
equivalence theorem is based on a separation of absorption and scattering. It is shown
that both methods give, in a statistical way, identical results for a wide variety of sce
narios. Both absorption methods are included in McSCIA, and it is shown that also
for a 3-D case both formulations give identical results. McSCIA limb profiles for atmospheres
with and without absorption compare well with the one of the state of the art
Monte Carlo radiative transfer model MCC++.
A simplification of the photon statistics may lead to very fast calculations of absorp
tion features in the atmosphere. However, these simplifications potentially introduce
biases in the results. McSCIA does not use simplifications and is therefore a relatively
slow implementation of the equivalence theorem. For the first time, however, the validity
of the equivalence theorem is demonstrated in a spherical 3-D radiative transfer
model.
Original language | Undefined/Unknown |
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Pages (from-to) | 1199-1248 |
Number of pages | 50 |
Journal | Atmospheric Chemistry and Physics Discussions |
Volume | 6 |
Publication status | Published - 2006 |