Three-Dimensional Radiative Transfer Modeling of Tropospheric Atmospheres

Abstract

Physically accurate visualizations of tropospheric atmospheres require three-dimensional (3D) radiative transfer (RT) codes capable of simulating scattering and absorption effects in and around natural clouds. This report describes an adaptation of the discrete ordinates technique for handling both thin (haze) and thick (natural cloud) optical media in a consistent manner. Media are modeled via uniform density cubical scattering cells (assuming that incident diffuse streams have uniform radiance over each input face). These assumptions allow the analytic evaluation of transmission factors and volume-averaged unscat- tered illumination across a cell in evaluating scattered streaming energies at each cell exit face. This initial analysis leads to an energy accounting technique which replaces energy not accounted for via transmission and diffuse single scattering with a surface scattering effect. Solar/lunar direct irradiance and graybody radiation are also considered. Monte Carlo analyses were used to determine the accuracy of the proposed methods. Path point-to-point calculations are described that adapt the outputs of the RT code to provide limiting path radiance information for visualization of could fields. An analysis of the scattering properties of aerosols as scale transformed Legendre polynomial expansions is also provided.

Document Details

Document Type

Technical Report

Publication Date

Mar 01, 1998

Accession Number

ADA342338

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