Abstract
The Cassini mission made an unexpected discovery when it found evidence of linear dune fields on Titan’s surface. The orientation of the dunes and their interaction with topography allow scientists to estimate the dominant wind direction on the surface of Titan. There is some consensus in the community that the dune-forming winds must be net westerly, however, there is an active debate about the dune-forming wind regime. This debate has been guided by several studies of Earth dune fields considered analogous to the Titan dunes including those in Namibia, the Sahara, the Serengeti, and China. Complicating this active debate about the surface wind regime is the fact that global circulation models (GCMs) have historically not been able to reproduce westerly surface winds in the tropics. Here we use the Titan Community Atmosphere Model (CAM) to quantify the impact of topography and an added torque on Titan’s dune-forming winds. Dunes tend to form at higher elevations on Titan, and adding topography to the model alters the near-surface wind directions, making them more westerly and consistent with the dune orientations. The addition of topography and added torque create a wind regime that is consistent with linear dunes in areas of stabilized sediment.
Highlights
The Cassini mission made an unexpected discovery when it found evidence of linear dune fields on Titan’s surface [1,2]
The presence and morphology of these dunes can aid our understanding of the dune-forming winds on Titan. Complicating this active debate about the surface wind regime is the fact that global circulation models (GCMs) have historically not been able to reproduce westerly surface winds in the tropics [5,11,12,13,14]
In this paper we present results from the Titan Community Atmosphere Model (CAM) GCM that includes the effects of topography and zonal nudging
Summary
The Cassini mission made an unexpected discovery when it found evidence of linear dune fields on Titan’s surface [1,2]. Cassini has imaged thousands of dunes throughout its mission, many of which are observed to divert around topography. The crestline orientations of the dunes and their interaction with topography allow scientists to estimate the dominant wind direction on the surface of Titan. The Titan surface wind regimes that have been proposed, mostly based on studies of morphologically similar Earth dune fields, are as follows: westerly winds with a fluctuating tidal component [1], bimodal (coming from two directions) westerly [2], bimodal easterly [5], unimodal westerly [4], bimodal and slightly westerly [6], and both unimodal and bimodal westerly winds [7]
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