Scale-Dependent Infrared Radiative Damping Rates on Mars and Their Role in the Deposition of Gravity-Wave Momentum Flux

Abstract

Using a Curtis matrix model of 15 micron CO2 radiative cooling rates for the Martian atmosphere, we have computed vertical scale-dependent IR radiative damping rates from 0-200 km altitude over a broad band of vertical wavenumbers m = 2pi (1-500 km)-1 for representative meteorological conditions at 40 deg N and average levels of solar activity and dust loading. In the middle atmosphere infrared (IR) radiative damping rates increase with decreasing vertical scale and peak in excess of 30 days-1 at ~50-80 km altitude, before gradually transitioning to scale-independent rates above ~100 km due to breakdown of local thermodynamic equilibrium. We incorporate these computed IR radiative damping rates into a linear anelastic gravity-wave model to assess the impact of IR radiative damping, relative to wave breaking and molecular viscosity, in the dissipation of gravity-wave momentum flux. The model results indicate that IR radiative damping is the dominant process in dissipating gravity-wave momentum fluxes at ~0-50 km altitude, and is the dominant process at all altitudes for gravity waves with vertical wavelengths approx less than 10-15 km. Wave breaking becomes dominant at higher altitudes only for "fast" waves of short horizontal and long vertical wavelengths. Molecular viscosity plays a negligible role in overall momentum-flux deposition. Our results provide compelling evidence that IR radiative damping is a major, and often dominant physical process controlling the dissipation of gravity wave momentum fluxes on Mars and therefore should be incorporated into future parameterizations of gravity-wave drag within Mars GCMs. Lookup tables for doing so, based on the current computations, are provided.

Document Details

Document Type

Technical Report

Publication Date

Jan 01, 2010

Accession Number

ADA522839

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