Abstract
Abstract A diagnostic technique has been developed to consistently derive all the dynamical and chemical tracer fields based on one or a few well-measured fields such as temperature and ozone distributions. The technique is based on the new Johns Hopkins University/Applied Physics Laboratory (JHU/APL) globally balanced 2D diagnostic model that couples the dynamics with photochemistry. This model is especially useful for studying the mesosphere and lower thermosphere where dynamics, radiation, and photochemistry strongly interact. The novelty of the diagnostic model is to derive the wave drag and eddy diffusion coefficient directly from the better-defined thermal forcing with its major contributions derived from the zonal mean components. The latter is also affected by the advective and diffusive transports. The derived tracer distributions together with input field(s) provide the necessary radiative and chemical heating rates for the calculation of the thermal forcing. Two numerical experiments with diffe...
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